Analytical Measurements in Aquatic Environments (Analytical Chemistry)

Co-published by IWA Publishing, Alliance House, 12 Caxton Street, London SW1H 0QS, UK Tel. +44 (0) 20 7654 5500, Fax +44 (0) 20 7654 5555 [email protected] www.iwapublishing.com ISBN 1843393069 ISBN13 9781843393061

CRC Press Taylor & Francis Group 6000 Broken Sound Parkway NW, Suite 300 Boca Raton, FL 33487-2742 © 2010 by Taylor and Francis Group, LLC CRC Press is an imprint of Taylor & Francis Group, an Informa business No claim to original U.S. Government works Printed in the United States of America on acid-free paper 10 9 8 7 6 5 4 3 2 1 International Standard Book Number: 978-1-4200-8268-5 (Hardback) This book contains information obtained from authentic and highly regarded sources. Reasonable efforts have been made to publish reliable data and information, but the author and publisher cannot assume responsibility for the validity of all materials or the consequences of their use. The authors and publishers have attempted to trace the copyright holders of all material reproduced in this publication and apologize to copyright holders if permission to publish in this form has not been obtained. If any copyright material has not been acknowledged please write and let us know so we may rectify in any future reprint. Except as permitted under U.S. Copyright Law, no part of this book may be reprinted, reproduced, transmitted, or utilized in any form by any electronic, mechanical, or other means, now known or hereafter invented, including photocopying, microfilming, and recording, or in any information storage or retrieval system, without written permission from the publishers. For permission to photocopy or use material electronically from this work, please access www.copyright.com (http:// www.copyright.com/) or contact the Copyright Clearance Center, Inc. (CCC), 222 Rosewood Drive, Danvers, MA 01923, 978-750-8400. CCC is a not-for-profit organization that provides licenses and registration for a variety of users. For organizations that have been granted a photocopy license by the CCC, a separate system of payment has been arranged. Trademark Notice: Product or corporate names may be trademarks or registered trademarks, and are used only for identification and explanation without intent to infringe. Library of Congress Cataloging-in-Publication Data Analytical measurements in aquatic environments / editors, Jacek Namiesnik, Piotr Szefer. p. cm. -- (Analytical chemistry series) Includes bibliographical references and index. ISBN 978-1-4200-8268-5 (hardcover : alk. paper) 1. Aquatic ecology--Mathematical models. 2. Chimometrics. I. Namiesnik, Jacek, 1949- II. Szefer, Piotr. III. Title. IV. Series. QH541.5.W3A565 2010 577.601’5118--dc22 Visit the Taylor & Francis Web site at http://www.taylorandfrancis.com and the CRC Press Web site at http://www.crcpress.com

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Contents

Preface ......................................................................................................................................... vii Editors .......................................................................................................................................... ix Contributors ................................................................................................................................ xi

Chapter 1

Strategy of Collecting Samples from an Aquatic Environment ............................... 1 Bogdan Zygmunt and Anna Banel

Chapter 2

Preservation and Storage of Water Samples ........................................................... 19 Marek Biziuk, Angelika Beyer, and Joanna Z˙ ukowska

Chapter 3

Application of Passive Sampling Techniques for Monitoring the Aquatic Environment ............................................................................................. 41 Graham A. Mills, Richard Greenwood, Ian J. Allan, Ewa Łopuchin, Janine Brümmer, Jesper Knutsson, and Branislav Vrana

Chapter 4

Modern Techniques of Analyte Extraction ............................................................ 69 Thaer Barri and Jan-Åke Jönsson

Chapter 5

Mineralization Techniques Used in the Sample Preparation Step ......................... 95 Henryk Matusiewicz

Chapter 6

Biota Analysis as a Source of Information on the State of Aquatic Environments .......................................................................................... 103 J.P. Coelho, A.I. Lillebø, M. Pacheco, M.E. Pereira, M.A. Pardal, and A.C. Duarte

Chapter 7

Speciation Analytics in Aquatic Ecosystems ....................................................... 121 A. de Brauwere, Y. Gao, S. De Galan, W. Baeyens, M. Elskens, and M. Leermakers

Chapter 8

Immunochemical Analytical Methods for Monitoring the Aquatic Environment ........................................................................................... 139 Javier Adrian, Fátima Fernández, Alejandro Muriano, Raquel Obregón, Javier Ramón, Nuria Tort, and M.-Pilar Marco v

vi

Chapter 9

Contents

Application of Biotests ......................................................................................... 189 Lidia Wolska, Agnieszka Kochanowska, and Jacek Namies´nik

Chapter 10 Total Parameters as a Tool for the Evaluation of the Load of Xenobiotics in the Environment ............................................................................................... 223 Tadeusz Górecki and Heba Shaaban El-Hussieny Mohamed Chapter 11 Determination of Radionuclides in the Aquatic Environment ............................. 241 Bogdan Skwarzec Chapter 12 Analytical Techniques for the Determination of Inorganic Constituents ............ 259 Jorge Moreda-Piñeiro and Antonio Moreda-Piñeiro Chapter 13 Analytical Techniques for the Determination of Organic and Organometallic Analytes ..................................................................................... 303 Erwin Rosenberg Chapter 14 Introducing the Concept of Sustainable Development into Analytical Practice: Green Analytical Chemistry ................................................................. 353 Waldemar Wardencki and Jacek Namies´nik Chapter 15 Chemometrics as a Tool for Treatment Processing of Multiparametric Analytical Data Sets ............................................................................................. 369 Stefan Tsakovski and Vasil Simeonov Chapter 16 Quality Assurance and Quality Control of Analytical Results ............................ 389 Ewa Bulska Chapter 17 Analytical Procedures for Measuring Precipitation Quality Used within the EMEP Monitoring Program ............................................................... 399 Wenche Aas Chapter 18 Life Cycle Assessment of Analytical Protocols ................................................... 413 Helena Janik and Justyna Kucin´ska-Lipka Chapter 19 Preparation of Samples for Analysis: The Key to Analytical Success ................ 431 Jacek Namies´nik and Piotr Szefer Index .......................................................................................................................................... 475

Preface Even a cursory perusal of any analytical journal must lead one to the conclusion that trace and ultratrace analyses is a domain of chemical analysis that is gaining in importance. This conclusion is corroborated not only by the feelings and opinions of analysts. According to the current IUPAC definition of the term “trace component,” the limit from which we can talk about trace analysis is the concentration of 100 ppm (100 μg g-1). Naturally, this limit is purely conventional and is not constant. As recently as 30 years ago, “trace analysis” was understood to denote activities aiming to determine components at a concentration level one order of magnitude higher, that is, below 1000 ppm, or 0.1%. Even today, the determination of components at a concentration level of 100 ppm, including samples with complex matrices, poses no major problems and is routine in many laboratories. This is mainly due to the rapid development of instrumentation—the science of the construction and use of monitoring and measuring devices. Hence, we can expect the definition of the term “trace component” to change again soon. There are three particular areas of science and technology that are spurring the development of analytical methods and techniques employed in the determination of low and very low analyte contents in samples of various kinds. They are • Technologies of the production of high-purity materials; to date, the purity of the purest man-made material is denoted by 11 N, which means that the sum total of all the impurities it contains does not exceed 10 −9%, or 10 ppt. • Genetic engineering and biotechnology. • Environmental protection, including the chemistry of specific elements in the environment. The determination of ever lower concentrations of analytes has brought into common use special ways of expressing such concentrations. Ecotoxicological considerations and the efforts undertaken to achieve an increasingly accurate description of the state of the environment pose a great challenge to analytical chemists in terms of the necessity of determining still lower concentrations of various analytes in samples having complex and even nonhomogenous matrices. The task can be accomplished by following either of two approaches: • The use of more sensitive and selective, or even specific, detectors: This approach is exemplified by the introduction of the photo-ionization detector (used in gas chromatography, [GC]), which is more sensitive and more selective than the flame-ionization detector hitherto commonly used in GC. • The introduction to analytical procedures of an additional step: The isolation and/or enrichment of analytes prior to their final determination. This extra step enables the interference caused by the components of a primary matrix (due to matrix simplification) to be removed; more importantly, however, it allows the analyte concentration to be increased to a level above the detection limit of the method or the analytical instrument used. With this approach, routine determinations of analytes at the ppb level and even the determination of analytes at concentration levels down to a fraction of ppq become possible. vii

viii

Preface

The term “analytics” is being used more and more frequently in the analytical chemistry literature. This newly coined expression emphasizes the interdisciplinary nature of methods of obtaining information about material systems, that is, methods that exceed the strict definition of analytical chemistry. Analytics, hitherto practiced mostly as analytical chemistry and, to a large extent identified with the work of chemists, has recently developed into a scientific discipline in its own right, whose role far exceeds chemistry alone and covers almost all branches of science and technology. Analytics has thus become an interdisciplinary science. This interdisciplinary nature is revealed through a variety of phenomena utilized at the measurement stage. Analytics is a scientific discipline embracing • • • • • • • •

Various areas of chemistry (particularly physical chemistry and biochemistry) Physics Computer science Electronics, automation, and robotics Material science Biology Instrumentation Chemometrics.

This book consists of a set of chapters focused on the most important aspects of analytical procedures for the determination of both inorganic and organic constituents in samples taken from different parts of aquatic ecosystems. Special attention is paid to • • • • • • • • • •

Handling of representative samples Samples of preservation techniques Extraction techniques Solvent-free sample preparation for analysis Application of biotests Green analytical chemistry—application of the concept of sustainability in analytical laboratories Application of the life cycle assessment approach Quality control and quality assurance of analytical results Enhanced techniques of sample preparation Hyphenated analytical techniques

We hope that this book will be a useful source of information for a wide spectrum of readers. Jacek Namies´nik and Piotr Szefer

Editors Jacek Namies´nik received his MSc (1972), PhD (1978), and DSc (1985) degrees from the Gdan´sk University of Technology (GUT). He has been employed at GUT since 1972. A full professor since 1998, he has also served as vice dean of the Chemical Faculty (1990–1996) and dean of the Chemical Faculty (1996–2000 and 2005–present). He has been the head of the Department of Analytical Chemistry since 1995, as well as chairman of the Committee of Analytical Chemistry of the Polish Academy of Sciences since 2007, and Fellow of the International Union of Pure and Applied Chemistry (IUPAC) since 1996. Dr. Namies´nik was director of the Center of Excellence in Environmental Analysis and Monitoring during 2003–2005. Among his scientific publications, there are seven books, over 300 papers, and more than 350 lectures and communications published in conference proceedings. He is the recipient of various awards, including Professor honoris causa from the University of Bucharest (Romania) (2000), the Jan Hevelius Scientific Award of Gdan´sk City (2001), and the Prime Minister of Republic of Poland Award (2007). He has seven patents to his name and his research interests include environmental analytics and monitoring and trace analysis. Piotr Szefer received his MSc (1972), PhD (1978), and DSc (1990) degrees from the Medical University of Gdan´sk (MUG). He was awarded Full Professorship in 2000. During 1990–2002, he was vice dean and dean of the Faculty of Pharmacy, MUG. Since 2000, he has been the head of the Department of Food Sciences, MUG. He has published approximately 200 papers, 17 book chapters, three books published by Elsevier and CRC Press\ Taylor & Francis, and approximately 300 symposial abstracts. He has been a member of approximately 30 national and international scientific associations and organizations (including nine editorial boards, e.g., The Science of the Total Environment), for example, the International Scientific Committee on Oceanic Research (SCOR) and WG Marine Board—European Science Foundation. He has visited 14 countries as a visiting professor or research scientist. Dr. Szefer has reviewed approximately 600 manuscripts for more than 60 journals. He received several scientific awards, for example, one from the Scientific Secretary of the Division VII of the Polish Academy of Sciences; nine awards from the Minister of Health; and a joint award from the Ministry of Environmental Protection, Natural Resources, and Forestry. His research is focused on food and marine chemistry, and bioanalytics.

ix

Contributors Wenche Aas Chemical Coordinating Center of the European Monitoring and Evaluation Program Norwegian Institute for Air Research Kjeller, Norway

A. de Brauwere Department of Analytical and Environmental Chemistry Vrije Universiteit Brussel Brussels, Belgium

Javier Adrian Networking Research Center on Bioengineering, Biomaterials and Nanomedicine Spanish National Research Council Barcelona, Spain

Janine Brümmer School of Biological Sciences University of Portsmouth Portsmouth, United Kingdom

Ian J. Allan Norwagian Institute for Water Research Oslo, Norway

Ewa Bulska Faculty of Chemistry Warsaw University Warsaw, Poland

W. Baeyens Department of Analytical and Environmental Chemistry Vrije Universiteit Brussel Brussels, Belgium

J.P. Coelho Department of Chemistry Centre for Environmental and Marine Studies University of Aveiro Aveiro, Portugal

Anna Banel Department of Analytical Chemistry Gdan´sk University of Technology Gdan´sk, Poland

A.C. Duarte Department of Chemistry Centre for Environmental and Marine Studies University of Aveiro Aveiro, Portugal

Thaer Barri Department of Analytical Chemistry Lund University Lund, Sweden Angelika Beyer Department of Analytical Chemistry Gdan´sk University of Technology Gdan´sk, Poland Marek Biziuk Department of Analytical Chemistry Gdan´sk University of Technology Gdan´sk, Poland

M. Elskens Department of Analytical and Environmental Chemistry Vrije Universiteit Brussel Brussels, Belgium Fátima Fernández Networking Research Center on Bioengineering, Biomaterials and Nanomedicine Spanish National Research Council Barcelona, Spain xi

xii

Contributors

S. De Galan Department of Analytical and Environmental Chemistry Vrije Universiteit Brussel Brussels, Belgium

A.I. Lillebø Department of Chemistry Centre for Environmental and Marine Studies University of Aveiro Aveiro, Portugal

Y. Gao Department of Analytical and Environmental Chemistry Vrije Universiteit Brussel Brussels, Belgium

Ewa Łopuchin Department of Analytical Chemistry Gdan´sk University of Technology Gdan´sk, Poland

Tadeusz Górecki Department of Chemistry University of Waterloo Waterloo, Ontario, Canada

M.-Pilar Marco Networking Research Center on Bioengineering, Biomaterials and Nanomedicine Spanish National Research Council Barcelona, Spain

Richard Greenwood School of Biological Sciences University of Portsmouth Portsmouth, United Kingdom Helena Janik Polymer Technology Department Gdan´sk University of Technology Gdan´sk, Poland Jan-Åke Jönsson Department of Analytical Chemistry Lund University Lund, Sweden Jesper Knutsson Water Environment Transport Chalmers University of Technology Göteborg, Sweden Agnieszka Kochanowska Department of Analytical Chemistry Gdan´sk University of Technology Gdan´sk, Poland Justyna Kucin´ska-Lipka Polymer Technology Department Gdan´sk University of Technology Gdan´sk, Poland M. Leermakers Department of Analytical and Environmental Chemistry Vrije Universiteit Brussel Brussels, Belgium

Henryk Matusiewicz Department of Analytical Chemistry Poznan´ University of Technology Poznan´, Poland Graham A. Mills School of Pharmacy and Biomedical Sciences University of Portsmouth Portsmouth, United Kingdom Heba Shaaban El-Hussieny Mohamed Department of Chemistry University of Waterloo Waterloo, Ontario, Canada Antonio Moreda-Piñeiro Department of Analytical Chemistry, Nutrition, and Bromatology University of Santiago de Compostela Santiago de Compostela, Spain Jorge Moreda-Piñeiro Department of Analytical Chemistry University of A Coruña A Coruña, Spain Alejandro Muriano Networking Research Center on Bioengineering, Biomaterials and Nanomedicine Spanish National Research Council Barcelona, Spain

xiii

Contributors

Jacek Namies´nik Department of Analytical Chemistry Gdan´sk University of Technology Gdan´sk, Poland

Bogdan Skwarzec Department of Analytical Chemistry University of Gdan´sk Gdan´sk, Poland

Raquel Obregón Networking Research Center on Bioengineering, Biomaterials and Nanomedicine Spanish National Research Council Barcelona, Spain

Piotr Szefer Department of Food Sciences Medical University of Gdan´sk Gdan´sk, Poland

M. Pacheco Department of Biology Centre for Environmental and Marine Studies University of Aveiro Aveiro, Portugal M.A. Pardal Zoology Department Institute of Marine Research University of Coimbra Coimbra, Portugal M.E. Pereira Department of Chemistry Centre for Environmental and Marine Studies University of Aveiro Aveiro, Portugal

Nuria Tort Networking Research Center on Bioengineering, Biomaterials and Nanomedicine Spanish National Research Council Barcelona, Spain Stefan Tsakovski Faculty of Chemistry University of Sofia Sofia, Bulgaria Branislav Vrana Slovak National Water Reference Laboratory Water Research Institute Bratislava, Slovakia Waldemar Wardencki Department of Analytical Chemistry Gdan´sk University of Technology Gdan´sk, Poland

Javier Ramón Networking Research Center on Bioengineering, Biomaterials and Nanomedicine Spanish National Research Council Barcelona, Spain

Lidia Wolska Department of Analytical Chemistry Gdan´sk University of Technology Gdan´sk, Poland

Erwin Rosenberg Vienna University of Technology Institute of Chemical Technologies and Analytics Vienna, Austria

Joanna Z˙ ukowska Department of Analytical Chemistry Gdan´sk University of Technology Gdan´sk, Poland

Vasil Simeonov Faculty of Chemistry University of Sofia Sofia, Bulgaria

Bogdan Zygmunt Department of Analytical Chemistry Gdan´sk University of Technology Gdan´sk, Poland

1

Strategy of Collecting Samples from an Aquatic Environment Bogdan Zygmunt and Anna Banel

CONTENTS 1.1 1.2

Introduction ........................................................................................................................ General Considerations ....................................................................................................... 1.2.1 Types of Samples .................................................................................................... 1.2.1.1 Discrete Sample ....................................................................................... 1.2.1.2 Composite Sample ................................................................................... 1.2.2 Basic Sampling Patterns ......................................................................................... 1.3 Sampling-Related Uncertainty ........................................................................................... 1.4 Basic Aspects of Strategies for Sampling Water and Sediments from Aquatic Environments ........................................................................................................ 1.4.1 Water Samples ........................................................................................................ 1.4.1.1 Sample Size .............................................................................................. 1.4.1.2 Sampling Location and Sampling Sites ................................................... 1.4.1.3 Sample Collection .................................................................................... 1.4.1.4 Sampling Frequency ................................................................................ 1.4.2 Sediments ................................................................................................................ 1.5 Selection of Sampling Equipment ...................................................................................... 1.5.1 Compatibility of Sampler Material with Water Samples ........................................ 1.5.2 Water Sampling Using Traditional Techniques ...................................................... 1.5.2.1 Manual Surface Water Samplers ............................................................. 1.5.2.2 Ground Water Samplers ........................................................................... 1.5.3 Automatic Water Sampling Systems ...................................................................... 1.5.4 Passive Samplers ..................................................................................................... 1.5.5 Sediment Samplers ................................................................................................. 1.6 Conclusions ......................................................................................................................... Acknowledgment ......................................................................................................................... References ....................................................................................................................................

1 2 3 3 3 5 5 8 8 8 9 9 11 11 12 12 13 13 14 14 14 15 16 16 16

1.1 INTRODUCTION The aquatic environment has played a crucial role since the very beginning of civilization. Leonardo da Vinci compared water with blood when he said: “water is the blood of the soil.” Indeed, “water” must have been one of the first words invented by human. Nowadays, the word water is commonly 1

2

Analytical Measurements in Aquatic Environments

used in two meanings. First, in a purely chemical sense, it represents the simple chemical compound with the formula H2O. Second, it stands for a wide range of different aqueous solutions, whose composition determines their usefulness or uselessness for a given purpose. The specific names of the solutions relate to the source or usage, for example, sea water, river water, ground water, rain water, drinking water, and irrigation water. Water, always a vital commodity for humans, is used for drinking, cooking, agriculture, transport, and recreation, among other purposes. To be applicable to a given purpose or suitable for various forms of life, water must satisfy certain requirements. The characteristics of water include a number of physicochemical parameters that should be monitored. Generally, water in any compartment of the environment is not completely isolated from its surroundings, and components are exchanged between the liquid phase and its immediate neighborhood. In the majority of cases it is the bottom sediment that releases or takes in the substances discharged into a water body. Therefore, any determination of water quality in a given compartment should include sediment analysis. Only a few physicochemical parameters can be measured by immersing the relevant instrument into a water body. In most cases a small fraction of a given water population or sample is collected and analyzed. The aim of taking samples or sampling is to extract a fraction of the water body that has chemical, physical, and biological properties identical to those of the bulk of the system to be studied. Ideally, all the characteristics of the sample, or at least, the parameters that are to be determined, should not change until the time of measurement. Only then can the results of the sample analysis be representative of the composition of the system under scrutiny. If analytical data are to be the source of reliable and valuable information on an aquatic environment, the samples should not only be properly collected, preserved, transported, and stored, but should also be taken at the proper place, time, frequency, and so on. All these factors must be properly planned, taking into account both the characteristics of the aquatic environment to be sampled and the feasibility of the task. This chapter looks at the sampling of different surface and ground waters. As sediments constitute an integral part of most aquatic environments, they too have been taken into consideration. It should be mentioned that precipitation and wet deposition also play an important role in the hydrological cycle, but the sampling problems are somewhat different and will not be dealt with here—they are comprehensively described elsewhere.1,2

1.2 GENERAL CONSIDERATIONS Sampling is the critical step in the whole analytical process; indeed, it is often the weakest link in the procedure and needs special care if the analytical results obtained are to be a source of reliable analytical information on a system.3 While designing the sampling process it should be remembered that • Samples that are not representative of the population studied are of little importance • Poor sampling procedures yield unrepresentative samples, which may make a disproportionately large contribution to the uncertainty of the analytical results • Sampling errors and analytical errors are independent of each other, so sampling-related errors cannot be corrected using laboratory blanks or control samples • Sampling errors can rarely be corrected without resampling and analysis • Contamination of samples and loss of analytes are common sources of errors in environmental measurements. There are many possible means of sampling with regard to techniques, devices, methodologies, types of samples, and so on.

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Strategy of Collecting Samples from an Aquatic Environment

1.2.1

TYPES OF SAMPLES4-6

The two basic types of water sample are discrete samples and composite samples; in the majority of cases, each type supplies slightly different information on the water body in question. They are depicted graphically in Figure 1.1. 1.2.1.1 Discrete Sample A discrete sample is a sample collected in a short period of time (generally <15 min) and deposited in a separate container. Discrete samples collected at a particular time and place represent only the composition of the source at that time and place. In fact, a single discrete sample gives only a snapshot of the situation. Nonetheless, discrete samples collected at many suitable intervals and locations can document compositional variations in time and space. 1.2.1.2 Composite Sample A composite sample consists of a series of smaller samples collected at regular intervals over a period of time and deposited in the same container. To some extent, composite samples represent the average characteristics of the source during the sampling period—they are useful in determining average pollutant concentrations or pollutant loads. The laboratory analysis of such samples is more cost-effective but generally yields less information.

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(a)

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FIGURE 1.1 Classification of water samples. (Based on Dick, M.E. 1996. In: L.H. Keith (ed.), Principles of Environmental Sampling, 2nd edition, pp. 237–258. American Chemical Society, Washington.)

4

Analytical Measurements in Aquatic Environments (a) Q

(b) Q

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FIGURE 1.2 Different types of discontinuous sampling techniques.

Samples can be collected continuously or discontinuously. According to ISO 5667-10,7 there are three main categories of discontinuous sampling (Figure 1.2). The samples can be analyzed separately or can be mixed to produce a composite sample. With the appropriate selection of sampling type, a composite sample can better characterize a given situation. In time-proportional sampling, equal volumes of water are collected at constant time intervals, but a composite sample produced in this way can yield a reliable average discharge or concentration only if these factors are relatively constant over the sampling period. In discharge-proportional sampling, the time intervals remain constant whereas the volume of each sample is proportional to the discharge. When the water flow rate changes, the so-called quantity-proportional or flow-weighted sampling can be useful. In this type, the volume of each sample is constant but the intervals between sampling events are inversely proportional to the flow rate. Sometimes, harmful substances are released into a water body for short periods, but only at irregular intervals. In such situations event-controlled sampling is useful (Figure 1.3).7 When some selected parameter (e.g., conductivity and temperature) reaches its threshold value, then an automatic pump sampler is switched on and a sample is collected.

5

Strategy of Collecting Samples from an Aquatic Environment P

t P

t

FIGURE 1.3

1.2.2

Event-controlled sampling.

BASIC SAMPLING PATTERNS

Once the sampling location has been established, the actual sampling sites must be selected to obtain reliable information on a given water body. The arrangement of sampling sites depends on the study’s objectives and the location’s complexity. The three basic patterns of sampling site selection are judgmental, systematic, and random (Figure 1.4).6,8 Combinations of any two are also used. The judgmental sampling pattern requires the smallest number of samples but the relative bias is the largest; the opposite holds for the random pattern, where the bias is the smallest but the number of samples is the largest. In scientific studies it is the judgmental approach that is most often applied, whereas for legal purposes absolutely random sampling is often needed.

1.3 SAMPLING-RELATED UNCERTAINTY The total uncertainty of the analytical results, which can be expressed quantitatively as the variance, is the sum of the variances related to the successive steps of the analytical process. Depending on the analytical task, the contribution of the variances of the particular steps can differ from each other quite considerably. In the case of samples collected from an aquatic environment, the total variance of the analytical result (sT2) can be expressed as follows: sT2 = sa2 + s2t + ss2 + sh2 + sp2 + sm2,

(1.1)

where the subscripts denote the variances: a, spatial; t, temporal; s, sampling proper; h, transport and storage; p, preparation; and m, measurement. If a sample is to describe a population averaged over space and time, spatial and temporal changes should be taken into account and included in the total variance of sampling. The later steps, that is, sample preservation, transport, storage, preparation for analysis, and the measurement proper, will be dealt with in the subsequent chapters of this book. Taylor9 uses the terms “sample

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Analytical Measurements in Aquatic Environments

FIGURE 1.4 Three basic patterns of sampling site selection. (Based on USEPA. 1995. Superfund Program Representative Sampling Guidance, Vol. 5: Water and Sediment. Available at http://www.epa.gov/tio/ download/char/sf_rep_samp_guid_water.pdf and Keith, L.H. 1991. Environmental Sampling and Analysis: A Practical Guide. Lewis, Michigan.)

variance” (s2sample) for the total variability up to the time the sample is poured into a container, “sampling variance” (s2sampling) for the variability inherent in the sampling proper, and “population 2 variance” (spopulation ) for spatial and temporal variability, which seems quite logical. However, in a large number of publications the term “sampling uncertainty” is used to express the variability of the spatial, temporal, and sample-collecting sources. This is the sense in which the term “sampling uncertainty” will be used in this chapter.

Strategy of Collecting Samples from an Aquatic Environment

7

In environmental analysis, especially in the determination of organic pollutants, sampling is considered to be the most critical step, the one that most often makes the greatest contribution to the total uncertainty of analysis. Therefore, to reduce the uncertainty of the analytical result, the closest attention should be paid to the sampling process. The main sources of error in sampling can be found in Madrid and Zayas.10 The most important sources of uncertainty seem to be the heterogeneity of an analyte within the matrix and the nonhomogeneity of the matrix itself. The uncertainty in the data can be reduced to acceptable levels by increasing the sample volume, number of samples, density of sampling sites, and frequency of sampling. However, reducing the uncertainty by increasing the number of samples can be cost-ineffective, since uncertainty is inversely proportional to the square root of that number. But again, this only holds if the procedure has been optimized; if not, the required uncertainty is unattainable. This was demonstrated by Minkkinen,11 who applied sampling theory in practice. Liess and Schulz12 have given a formula for predicting the number of samples required for an assumed uncertainty: s 2, N = 4 ___ xd

( )

(1.2)

where s is the estimated standard deviation of the arithmetic mean of all single samples, x is the estimated arithmetic mean of all single samples, and d is the tolerable uncertainty of the result, for example, 20% (d = 0.2). Samples are collected in order to obtain information on a given environmental compartment, and so the sampling sites should be located such that the collected samples represent the environmental compartment under study with respect to a selected parameter. The optimal selection of sampling sites depends on the aim of the program. It is often the case that the location of the sampling sites, among other factors, is predetermined, before the pollution status has been defined. The uncertainty in status is considerable even if it has been preceded by exploratory sampling, the aim of which is to establish species of concern, the approximate range of concentration, variability, and so on. Uncertainties will also result from inappropriate timing if temporal fluctuations occur. Sample collection may be a source of uncertainty for quite a few reasons. Some target analytes may be deposited on the contact surfaces of the sampling device together with suspended matter. Volatiles may be released, be adsorbed on, or react with the sampler material or with external agents, or they may decompose in the presence of elevated temperatures, UV radiation, microbial activity, and so on. Hence, sampling should include a special quality control procedure for estimating and possibly reducing the uncertainty related to particular phenomena. The essential components of a sound quality control system, according to Keith,8 are the consistent use of qualified personnel, reliable, and well-maintained equipment, appropriate calibration of standards, and the supervision of all operations by management and senior personnel. Analytical protocols should include all the steps, in order to check for possible contamination of the sample or loss of analytes that can lead to a change in the analyte concentration. First, routine tests should be conducted to check the effectiveness of the cleaning of sampling devices and sample containers. This can be done in the laboratory by applying equipment or rinsate blanks. The blanks should be collected after each decontamination and before resampling, and where necessary, corrective action should be taken. The tests should be made to check whether the material, from which the device/container is made and which is in contact with the sample, does not adsorb or react with or release relatively significant amounts of target analytes. Field blanks are used to provide routine contamination tests. They are samples that do not contain target analytes and have a matrix composition similar to that of the analyzed media. Examples of blanks are water collected from a nonpolluted water body, or deionized, or distilled water. Field blanks are delivered to the sampling site and treated in exactly the same way as real samples; they take account not only of the uncertainty of sampling but also of transport and storage.

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Analytical Measurements in Aquatic Environments

The contribution made by the last two steps can be discovered by applying a field check sample, which is obtained by dividing the problem sample into two and spiking one subsample with a target analyte. Recovery is then determined under different conditions of light, temperature, pH, and so on, in order to select the best sample storage conditions. Replicate samples are used to indicate sample uncertainty, which shows the contribution of sampling and sample handling to the overall uncertainty. Thompson et al.13 have shown quality control in sampling to be practicable in sampling procedures requiring a combination of sample increments to form a composite sample. It is very important, however, that the approach proposed does not require any extra time and resources beyond those used for the normal sampling procedure that precedes analysis.

1.4 BASIC ASPECTS OF STRATEGIES FOR SAMPLING WATER AND SEDIMENTS FROM AQUATIC ENVIRONMENTS 1.4.1

WATER SAMPLES

Independently of the monitoring aim, samples should be representative of the water studied. Sampling strategies, as well as the techniques, the requirements, and the recommendations for the routine collection of representative water samples, are described in the U.S. National Field Manual and elsewhere.14-16 In the formulation of strategies for sampling water from an aquatic environment, several factors should be looked at. Which of these should be taken into account in a given situation depends on the objective of sampling and the type of water body to be analyzed. The most important factors are the selection of sampling location (general position in the water body) and sampling sites (exact position), the size of samples and the number to be taken at each site, the frequency and timing of sampling, and the manner in which the sample is taken. The nature of water also has an important influence on the sampling strategy, which depends on whether sampling is carried out for exploratory or monitoring purposes. 1.4.1.1 Sample Size The sample volume depends on the target analytes and their expected concentrations, the quantification limit of the analytical procedure, the matrix composition, and the homogeneity of the medium. The sample volume should be such that after enrichment, the concentrations of target analytes are higher than the quantification limit (LOQ) of the final analytical procedure. If different procedures are used for different analytes, then the volume should be increased. It should be increased still further if replicate analyses are to be carried out. It is not uncommon that water contains some particulate matter (PM) of different compositions and surface areas. The distribution of particulate matter is by nature less homogenous than that of dissolved substances. This can introduce some inhomogeneity in the concentrations of soluble substances: some of these are adsorbed on the PM, and their content in the liquid phase decreases consequently. This is especially important when organic pollutants are characterized by high octanol–water partition coefficients. If only the dissolved fraction of an analyte is of interest, the results will depend strongly on the concentration of suspended matter, and larger samples will have to be taken to reach the required LOQ. If the analytical procedure for a given matrix is still undergoing development, then the sample volume must be larger still. The accuracy and precision of the analytical procedure and the limiting uncertainty of the results determine the number of necessary replicate measurements and hence the minimum sample volume. On the other hand, the sample should only be as large as need be, since larger samples mean higher costs, not to mention the inconveniences of transport, storage, material use, and disposal. Taking into account present regulations and available analytical procedures, it can be estimated that approximately 100 mL samples should be sufficient for heavy metal determinations. However, if organic analytes are of interest, then samples of a volume of typically 1 L, but sometimes also 3 L, and in some cases even 20 L are required.12 There are also situations where much larger (e.g., 100 L) samples must be collected in order to achieve the desired detection limit.

Strategy of Collecting Samples from an Aquatic Environment

9

1.4.1.2 Sampling Location and Sampling Sites The sampling location is selected in accordance with the measurement objectives. If it is the efficiency of a water treatment plant that is to be determined, the sampling sites should be located above and below the points of water entry to the plant. For studying the effect of effluent discharge on water quality in a river, water samples should be collected upstream and downstream of the outfall. The selection of sampling site depends on the variability of the system and the type of information to be acquired. This has been described in guidelines and scientific journals. Dixon et al.17 described a new approach to optimizing the selection of river sampling sites based on the geographical information system, graph theory, and a simulated annealing algorithm. For measuring the quantity of pollutants carried by a river, the sampling sites should represent the water body as a whole. Boundaries such as banks, surface, bottom, and the confluences of streams or other rivers should thus be avoided, since any samples collected there will generally be unrepresentative. For studying the effect of the discharge of wastewater, industrial effluents, and so on, on river water quality, samples should be taken downstream, at a location where mixing is complete. For monitoring the quality of water taken for a particular purpose, the sampling site should be situated close to the abstraction point. In the case of lakes and reservoirs, the heterogeneity related to thermal stratification, inflowing streams, morphology, and even wind needs to be taken into consideration during site selection. For obtaining a sample representative of the vertical cross-section of a stratified water body, for example, stratified estuaries, depth-integrating samplers can be used. Samples can be collected at different depths and mixed to obtain a composite sample. The surface water layer and the near-bottom layer can differ considerably, and so samples should be collected some distance from the bottom and surface. Some pollutants concentrate on the water surface, and so then the sea surface microlayer of approximately 50 mm thickness should be collected using special samplers.18 Ground water samples can be collected from monitoring or supply wells. Their location is not always straightforward—generally such water is sampled over hot spots and near locations following the subterranean stream in order to detect plume profile movements.19 The depth of the well and the characteristics of the surrounding land surface and upstream activities can help in the interpretation of results. 1.4.1.3 Sample Collection 1.4.1.3.1 Surface Waters How should samples be taken? Small streams are generally shallow, so samples can be taken manually from the bank or from some shallow spot in the stream simply by immersing a bottle in the water (Figure 1.5).

FIGURE 1.5 A hand-held open-mouth bottle sampler. (Based on Lane et al. 2003. U.S. Geological Survey Techniques of Water-Resources Investigations. Book 9, Chapter A2. Available at http://pubs.water.usgs.gov/ twri9A2/ (accessed March 20, 2003).)

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Analytical Measurements in Aquatic Environments

FIGURE 1.6 Sampling of water from given depths.

In the case of larger streams and rivers, samples can be taken from river banks, platforms, and bridges (Figure 1.6). Water samples from large rivers, estuaries, and the sea can be collected in using flasks that are hand-held (polyethylene-gloved hand, mouth down) or attached to a 3–4 m telescopic tube, from platforms with the aid of a pump, and from oar-propelled rubber dinghies, and also with special bottles for discrete depth sampling (Figure 1.7).

FIGURE 1.7

Sampling of water at discrete depths with the Ruttner sampler.

Strategy of Collecting Samples from an Aquatic Environment

11

The dinghy should be located upwind of the motor launch to prevent the sampled water from being polluted with exhaust gases from the latter. To sample water or sediments close to a dam, samplers can be immersed in water from helicopters;21 their use for sampling was comprehensively described by Krinitz et al.22 1.4.1.3.2 Ground Waters Ground water is a very complex matrix and can vary considerably from one aquifer to another; the physical characteristics of wells also differ. All these factors and also the target analytes must be considered when selecting sampling equipment that allows the representativeness and integrity of the samples to be maintained. Ground water samples must not contain particulate matter and must be protected from the air throughout the sampling process because aeration can drastically affect sample integrity.23-25 1.4.1.4 Sampling Frequency The frequency of sampling is an important factor. In monitoring programs, the frequency and also locations are generally established by the regulatory agencies. The frequency depends on the purpose of sampling. Where changes in environmental parameters or quality are the object of study, the sampling frequency should be at least twice the frequency of the variation.26 The multifarious aspects of sampling are discussed in a number of papers.27,28

1.4.2

SEDIMENTS

Pollutant adsorption on the solid material present in an aquatic environment depends strongly on the size of particles and their composition. Sediments containing particles 0.06–0.2 mm in size and larger have a rather low adsorption capability and pollutants are generally not associated with them. Fine-grained silts and clays have a much larger specific surface area and can therefore adsorb some organic and inorganic pollutants quite efficiently. These should be sampled and analyzed for their pollutant content in order to evaluate the threat to living organisms. In shallow waters sediments can be sampled manually with a spoon or a scoop (Figure 1.8) or with corers (Figure 1.9); in deep waters different kinds of dredges and special corers are operated from on board ships (Figure 1.10).

FIGURE 1.8 Collection of sediment samples from shallow water with a scoop.

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Analytical Measurements in Aquatic Environments

FIGURE 1.9 Collection of sediment samples from shallow water with a manual corer.

FIGURE 1.10 a ship.

Collection of sediment samples from deep water with a dredge operated from on board

1.5 SELECTION OF SAMPLING EQUIPMENT 1.5.1

COMPATIBILITY OF SAMPLER MATERIAL WITH WATER SAMPLES29

When selecting equipment for sampling water, the prime consideration is the material from which the parts in contact with the sample have been made. This can be various organic polymers, metals, and glass. The material selected should not release compounds interfering with the determination of target analytes and should neither adsorb nor react with these analytes. Hence, the nature of the analytes and the properties of the sampler material will be crucial factors in selecting the equipment for a given task. In general, organic polymers are incompatible with most organic analytes, which

Strategy of Collecting Samples from an Aquatic Environment

13

can dissolve in or be leached out of such materials, and this may lead to negative or positive errors, respectively. Plastics such as fluorocarbon polymers (Teflon, Kynar, and Tefzel), polypropylene, polyethylene (linear), polyvinyl chloride, Silicone, and Nylon can all be used for inorganic sampling. Fluorocarbon polymers are completely inert to most inorganic analytes, Silicone is highly porous and relatively inert to the majority of such analytes, and the others are also relatively inert to them. Possible limitations are due to the fact that fluorocarbons can be a source of fluoride and Silicone a source of silicon-containing compounds. In general, organic materials should not be used for organic analytes, with the exception of fluorocarbon polymers, which sorb only certain organics, and Nylon, which can only be used for chlorofluorocarbons. 316-grade stainless steel, which has the highest resistance to corrosion, can be used for all organics, provided that it is not corroded. It can also be used for submersible pump casings, as long as its negative effects on inorganic compounds are minimized, for example, by using fluorocarbon polymers for sample-wetted components. If corroded, the material is a potential source of Cr, Ni, Fe, and possibly Mn and Mo. For surface water sampling, the equipment must have a plastic coating. The less corrosion-resistant 304-grade stainless steel can be used only for organics and then only if it is not corroded. Other metallic materials like brass, iron, copper, aluminum, and galvanized and carbon steels are unsuitable for inorganic compounds; however, these materials are compatible with organics as long as they are not corroded. They are routinely used for CFC monitoring. Borosilicate glass and ceramics are inert materials and have great chemical stability; the weak point about glass, however, is its fragility. Glass can be used for both organics and inorganics, but one should be mindful of the fact that it is a potential source of boron and silicon and cannot be used if these elements are to be determined. Obviously, the equipment must be thoroughly cleaned before sampling. The cleaning procedures depend mainly on the target analytes (analytes to be determined) and, to some extent, also on the matrix; there are a few protocols for the removal of possible interfering substances.24 If the sample to be analyzed has a similar or a higher concentration of analytes than the sample analyzed before, then the same equipment can be used. A brief discussion of this problem regarding organic analytes is given in Hildebrandt et al.19 If gloves are used to handle equipment they should be disposable and powderless; before use, they should be examined visually for defects. Namies´nik et al.30 discuss at length the various problems encountered in environmental sampling and describe a large number of samplers for collecting water and sediments.

1.5.2

WATER SAMPLING USING TRADITIONAL TECHNIQUES

A large number of samplers for sampling water from different aquatic environments have been designed and put on the market by various manufacturers. The use of automatic samplers is increasing since they have quite a few significant advantages over manual samplers, which are still widely used. Some can be used for grab or discrete samples, and others for composite samples. The sampling devices should permit rapid immersion in water, drift minimally from the vertical position, have a suitable closing/sealing mechanism to retain the sample, have the appropriate sample capacity, and be easy to use. Sampler selection depends, among other things, on the location of the sampling site, the depth at which samples should be taken, how far from the bottom it is situated, the size and type of sample, site accessibility, and the type of matrix. 1.5.2.1 Manual Surface Water Samplers 1.5.2.1.1 Samplers for Small Depths For taking small samples close to the bank of a water body, a held-hand open-mouth bottle sampler can be used, provided that the depth and the water velocity are smaller than the minimum for

14

Analytical Measurements in Aquatic Environments

depth-integrating samplers. Should large-volume samples be needed, for example, in the trace analysis of surface water for organics, the sample can be pumped through tubes into the proper container from platforms, from buoys far away from the vessel or from an oar-propelled rubber dinghy (upwind of the motor boat). 1.5.2.1.2 Deep-Water Samplers For taking water from a selected depth, samplers with special systems enabling the container to be filled with water at the required depth and transporting the sample in undisturbed form to the analyst are used. The simplest sampler of this type is a weighted bottle stoppered with a cork connected to the bottle neck by a line used to open the bottle at the required depth.12 During sampling, the water sample comes into contact with the air present in the bottle. This can be deleterious to many analytical tasks. Fortunately, there are a number of water samplers with which nonaerated samples can be collected at a selected depth: the Ruttner sampler, the biochemical oxygen demand (BOD) sampler, and the volatile organic compounds (VOC) sampler are among the most common.20 To collect instantaneous discrete samples so-called thief samplers are used, which are available in different sizes, mechanical configurations, and construction material. The most commonly used are the Kremmer sampler, Van Dorn sampler, and the double check-valve bailer with a bottom-emptying device.20 1.5.2.2 Ground Water Samplers The most important factors in selecting samplers for ground water are the type and location of the well, depth of water with respect to the land surface, the physical characteristics of the well, and target analytes. For ground water monitoring, pumps designed specifically for monitoring wells or pumps installed in supply wells, bailers, over point, and thief-type samplers are most commonly used. The above-mentioned equipment is described in the U.S. Geological Survey Manual.20 Parker31 compared the ability of different ground water sampling devices to deliver representative samples. He found that grab samplers, positive displacement devices, and suction-lift devices can, under certain conditions, alter the chemistry of ground water samples, and that gas-lift pumps, older types of submersible centrifugal pumps, and suction-lift devices should not be recommended for sampling sensitive analytes such as volatile organics and inorganics, or inorganics that undergo oxidation and precipitation reactions. The best recoveries of sensitive analytes were obtained with bladder pumps.

1.5.3

AUTOMATIC WATER SAMPLING SYSTEMS

Though widely applied, manual sampling has certain drawbacks. The most important are the difficulty in performing event-triggered sampling, the inconvenience of collecting samples at certain hours or unpredictable times, and the dangers to which the person carrying out the sampling is exposed in some situations. For these and other less important reasons, automatic sampling is becoming increasingly popular and advances in their construction are taking place. The basic components of an automatic sampling system are presented in Figure 1.11. Automatic sampling is less labor-intensive and often produces more consistent results; it is also to be recommended in the situations mentioned above.5,32,33

1.5.4

PASSIVE SAMPLERS

The limitations of conventional sampling in the monitoring of aquatic environments have led to the introduction of passive samplers, which are now being used more often. The samples taken with these devices allow very low concentrations of pollutants to be determined and episodic pollution events to be detected: both could be missed with the conventional approach. Passive samplers are designed to accumulate target analytes over a long time. The basic difference between passive and conventional sampling is that the former collects only selected groups of components, including

15

Strategy of Collecting Samples from an Aquatic Environment

3

4

2

1

FIGURE 1.11 Basic components of an automatic sampler: 1—sample intake; 2—sample transport tube; 3—pump controller; and 4—sample bottles. (Based on Dick, M.E. 1996. In: L.H. Keith (ed.), Principles of Environmental Sampling, 2nd edition, pp. 237–258. American Chemical Society; and Dick, E.M. 1994. In: B. Markert (ed.), Environmental Sampling for Trace Analysis, pp. 255–278. VCH.)

target analytes (the best passive samplers collect only these), leaving the water behind, whereas the latter collect the whole sample, which often means a large sample volume. Martin et al.34 compared the monitoring of ground water for its content of polycyclic aromatic hydrocarbons and benzene, toluene, and xylenes using time-integrating ceramic dosimeters with conventional water sampling. Their results show that ceramic dosimeters are suitable for monitoring aqueous pollutant concentrations over long periods of time without any artifacts arising from pumping, handling, and storing the water samples. The first passive samplers were developed for monitoring inorganic compounds in surface water in the mid-1970s.35 Since the first application of a passive sampler for collecting organic pollutants in soil in 1985,36 devices for sampling organics from aquatic environments have developed apace. The techniques and corresponding sampling devices have been comprehensively discussed in a number of reviews and original papers.37-43 In all these devices, a barrier is applied, which allows the more or less selective transfer of target analytes from the aqueous matrix to the accumulating medium. Ongoing research into sampling devices aims to increase their selectivity, widen their range of application, and improve their robustness. However, passive sampling will no doubt gain broader acceptance in regulatory programs once quality assurance, quality control, and validation methods have been developed.

1.5.5

SEDIMENT SAMPLERS

As the data indicating the interdependence between pollution of the sediment and aqueous phase in the aquatic environment are increasing, so is information on sediment pollution clearly taking on a greater significance. A good selection of sediment samplers is commercially available; they are described in a number of papers and sampling guidelines.6,44-53 The main factors to be taken into consideration when choosing a sampler are the depth of water and the sample type (grab or core). For taking grab samples of the upper sediment layer in relatively calm and shallow waters, spoons or scoops can be used (Figure 1.8). These are simple and inexpensive, but the samples are poorly defined with respect to area and depth, and the finest particles may be washed out as the sample is retrieved through the water column. In deeper waters, dredges of various sizes and designs are used for collecting the upper layer of sediment; the integrity of the sample collected may be disturbed to

16

Analytical Measurements in Aquatic Environments

a greater or a lesser extent. They generally require a boat or a barge fitted with a winch (Figure 1.10), although there are some that can be operated manually. Vertical pollutant profiles in sediments can be determined in samples collected with multilevel sampling devices or corers. Manual corers are simple, easy to use, clean, and decontaminate (Figure 1.9); they can be deployed by hand or with the aid of a hammer. Though recommended for shallow water, corers can be extended for use in deeper waters. In general, they are applicable to clayey and sandy sediments, but the use of inserts is recommended for the latter. The main shortcoming of this technique is that the samples are relatively small in size. For larger depths and up to moderately strong water currents, specially designed gravity corers, equipped with stabilizing fins and adjustable weights, are in use. Vibro-corers are another type, which enter the sediment with the aid of the vibration from an electric motor.

1.6

CONCLUSIONS

The sampling of the aquatic environment is the critical step in the determination of organic and inorganic pollutants, and hence the suitability of water for a given purpose and for living organisms. Very often, however, the sampling process itself contributes to the total uncertainty of the analytical results in the highest degree. To obtain reliable information on the quality of a given water compartment, the sampling program must be meticulously planned. The sampling strategy includes the selection of the sampling location and sampling sites, frequency of sampling, sample size, the number of samples, and selection of sampling technique and equipment, although in some situations certain parameters are stipulated by the regulatory agencies. The above factors emerge from the purpose of sampling, which defi nes the permissible uncertainty of sampling and limit of quantitation. The correct decisions on water use and management can only be made if the data produced are reliable. Therefore, quality control procedures must be applied to test and correct this crucial step of chemical analysis. In the optimization of the sampling process, the costs must also be taken into account.

ACKNOWLEDGMENT The authors thank Professor Jacek Namies´nik for the fruitful discussions they were able to have with him.

REFERENCES 1. Skarzynska, K., Z. Polkowska, and J. Namiesnik. 2006. Samples handling and determination of physicochemical parameters in rime, hoarfrost, dew, fog and cloud water samples—a review. Pol. J. Environ. Stud. 15: 185–209. 2. Skarzynska, K., Z. Polkowska, A. Przyjazny, and J. Namiesnik. 2007. Application of different sampling procedures in studies of composition of various types of runoff waters. Crit. Rev. Anal. Chem. 37: 91–105. 3. Cochran, W.G. 1977. Sampling Techniques, 3rd edition. Wiley, USA. Available at http://www.amazon. com/Sampling-Techniques-3rd-William-Cochran/dp/047116240X/ref=si3_rdr_bb_product. 4. ISO 6107-2. 2006. Water quality, Vocabulary. Part 2. 5. Dick, M.E. 1996. Automatic water and wastewater—sampling, Chapter 13. In: L.H. Keith (ed.), Principles of Environmental Sampling, 2nd edition, pp. 237–258. American Chemical Society, Washington. 6. USEPA. 1995. Superfund Program Representative Sampling Guidance, Vol. 5: Water and Sediment. Available at http://www.epa.gov/tio/download/char/sf_rep_samp_guid_water.pdf. 7. ISO 5667-10. 2004. Water quality—sampling. Part 10: Guidance on sampling of waste waters. 8. Keith, L.H. 1991. Environmental Sampling and Analysis: A Practical Guide. Lewis, Michigan. 9. Taylor, J.K. 1996. Defining the accuracy, precision, and confidence limits of sample data, Chapter 4. In: L.H. Keith (ed.), Principles of Environmental Sampling, 2nd edition, pp. 77–83. American Chemical Society, Washington.

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10. Madrid, Y. and Z.P. Zayas. 2007. Water sampling: Traditional methods and new approaches in water sampling strategy. Trends Anal. Chem. 26: 293–299. 11. Minkkinen, P. 2004. Practical applications of sampling theory. Chemom. Intell. Lab. Syst. 74: 85–94. 12. Liess, M. and R. Schulz. 2000. Sampling methods in surface waters, Chapter 1. In: L.M.L. Nollet (ed.), Handbook of Water Analysis, pp. 1–24. Marcel Dekker, New York. 13. Thompson, M., B.J. Coles, and J.K. Douglas. 2002. Quality control of sampling: Proof of concept. Analyst 127: 174–177. 14. U.S. Geological Survey. 2006. Collection of water samples (version 2.0): U.S. Geological Survey Techniques of Water-Resources Investigations, Book 9, Chapter A4. Available at http://pubs.water.usgs. gov/twri9A4/ (accessed September 2006). 15. Fresenius, W., K.E. Quentin, and W. Schneider. 1988. Water Analysis: A Practical Guide to Physicochemical and Microbiological Water Examination and Quality Assurance. Springer, Germany. 16. Hermanowicz, W., J. Dojlido, W. Dozanska, B. Koziorowski, and J. Zerze. 1999. Fizyko–chemiczne Badanie Wody i S´cieków. Arkady, Warszawa. 17. Dixon, W., G.K. Smyth, and B. Chiswell. 1999. Optimized selection of river sampling sites. Water Res. 33: 971–978. 18. Wardencki, W. and J. Namiesnik, 2002. Sampling water and aqueous solutions, Chapter 2. In: J. Pawliszyn (ed.), Sampling and Sample Preparation for Field and Laboratory. Fundamentals and New Directions in Sample Preparation, pp. 33–60. Elsevier, Amsterdam. 19. Hildebrandt, A., S. Lacorte, and D. Barcelo. 2006. Sampling of water, soil and sediment to trace organic pollutants at a river-basin scale. Anal. Bioanal. Chem. 386: 1075–1088. 20. Lane, S.L., S. Flanagan, and F.D. Wilde. 2003. Selection of equipment for water sampling (version 2.0): U.S. Geological Survey Techniques of Water-Resources Investigations. Book 9, Chapter A2. Available at http://pubs.water.usgs.gov/twri9A2/ (accessed March 20, 2003). 21. Wiegel, S., A. Aulinger, R. Brockmeyer, H. Harms, J. Loffler, H. Reincke, R. Schmidt, B. Stachel, W. von Tumpling, and A. Wanke. 2004. Pharmaceuticals in the river Elbe and its tributaries. Chemosphere 57: 107–126. 22. Krinitz, J., B. Stachel, and H. Reincke. 2000. Stoffkonzentrationen in mittels Hubschrauber entnommenen Elbewasserproben (1979 bis 1998). Rapport Arbeitsgemeinschaft für die Reinhaltung der Elbe, Hamburg. 23. Kent, T.R. and K.E. Payne. 1996. Sampling groundwater monitoring wells special quality assurance and quality control considerations, Chapter 21. In: L.H. Keith (ed.), Principles of Environmental Sampling, 2nd edition, pp. 337–392. American Chemical Society, Washington. 24. USEPA REGION I. 1996. Low stress (low flow) purging and sampling procedure for the collection of ground water samples from monitoring wells (Groundwater Sampling, January 9, 2003). 25. Smith, J.S, D.P. Steele, J.M. Malley, and M.A. Bryant. 1996. Groundwater sampling, Chapter 22. In: L.H. Keith (ed.), Principles of Environmental Sampling, 2nd edition, pp. 393–398. American Chemical Society, Washington. 26. Barcelona, M.J. 1996. Overview of the sampling process, Chapter 2. In: L.H. Keith (ed.), Principles of Environmental Sampling, 2nd edition, pp. 41–61. American Chemical Society, Washington. 27. Shaw, R.W., M.V. Smith, and R.J. Pour. 1984. The effect of sample frequency on aerosol mean values. J. Air Pollut. Control Assoc. 34: 839–841. 28. Nelson, J.D. and R.C. Ward. 1981. Statistical considerations and sampling techniques for ground-water quality monitoring. Ground Water 19: 617–625. 29. Parker L.V. and T. Ranney. 2000. Decontaminating materials used in ground water sampling devices: Organic contaminants. Ground Water Monit. Rev. 20: 56–68. 30. Namiesnik, J., J. Łukasiak, and Z. Jamrogiewicz. 1995. Pobieranie Próbek S´rodowiskowych Do Analizy. PWN, Warszawa. 31. Parker, L.V. 1994. The effects of ground water sampling devices on water quality: A literature review, pp. 130–141. GWMR. Spring. 32. Dick, E.M. 1994. Water and wastewater sampling for environmental analysis, Chapter 12. In: B. Markert (ed.), Environmental Sampling for Trace Analysis, pp. 255–278. VCH, Weinheim. 33. USEPA. 1992. NPDES Storm Water Sampling Guidance Document. Available at http://www.epa.gov/ npdes/pubs/owm0093.pdf. 34. Martin, H., B.M. Patterson, and G.B. Davis. 2003. Field trial of contaminant groundwater monitoring: Comparing time-integrating ceramic dosimeters and conventional water sampling. Environ. Sci. Technol. 37: 1360–1364. 35. Benes, P. and E. Steinnes. 1974. In situ dialysis for the determination of the state of trace elements in natural water. Water Res. 8: 947–953.

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36. Coutant, R.W., R.G. Lewis, and J. Mulik. 1985. Passive sampling devices with reversible adsorption. Anal. Chem. 57: 219–223. 37. Stuer-Lauridsen, F. 2005. Review of passive accumulation devices for monitoring organic micropollutants in the aquatic environment. Environ. Pollut. 136: 503–524. 38. Gorecki, T. and J. Namiesnik. 2002. Passive sampling. Trends Anal. Chem. 21: 276–291. 39. Namiesnik, J., B. Zabiegala, A. Kot-Wasik, M. Partyka, and A. Wasik. 2005. Passive sampling and/or extraction techniques in environmental analysis: A review. Anal. Bioanal. Chem. 381: 279–301. 40. Vrana, B., G.A. Mills, I.J. Allan, E. Dominiak, K. Svensson, J. Knutsson, G. Morrison, and R. Greenwood 2005. Passive sampling techniques for monitoring pollutants in water. Trends Anal. Chem. 24: 845–868. 41. Bopp, S., W. Hansjorg, and K. Schirmer. 2005. Time-integrated monitoring of polycyclic aromatic hydrocarbons (PAHs) in groundwater using the ceramic dosimeter passive sampling device. J. Chromatogr. A 1072: 137–147. 42. Kot-Wasik, A., B. Zabiegala, M. Urbanowicz, E. Dominiak, A. Wasik, and J. Namies´nik. 2007. Advances in passive sampling in environmental studies. Anal. Chim. Acta 602: 141–163. 43. Vermeirssen, E.L.M., O. Korner, R. Schonenberger, M.J.F. Suter, and P. Burkhardt-Holm. 2005. Characterization of environmental estrogens in river water using a three pronged approach: Active and passive water sampling and the analysis of accumulated estrogens in the bile of caged fish. Environ. Sci. Technol. 39: 8191–8198. 44. Heim, S., M. Ricking, J. Schwarzbauer, and R. Littke. 2005. Halogenated compounds in a dated sediment core of the Teltow canal, Berlin: Time related sediment contamination. Chemosphere 61: 1427–1438. 45. Chang, B.V., C.S. Liao, and S.Y. Yuan. 2005. Anaerobic degradation of diethyl phthalate, di-n-butyl phthalate, and di-(2-ethylhexyl) phthalate from river sediment in Taiwan. Chemosphere 58: 1601–1607. 46. Borghini, F., J.O. Grimalt, J.C. Sanchez-Hernandez, R. Barra, C.J.T. Garcia, and S. Focardi. 2005. Organochlorine compounds in soils and sediments of the mountain Andean Lakes. Environ. Pollut. 136: 253–266. 47. Zhang, Q. and G. Jiang. 2005. Polychlorinated dibenzo-p-dioxins/furans and polychlorinated biphenyls in sediments and aquatic organisms from the Taihu Lake, China. Chemosphere 61: 314–322. 48. Zygmunt, B. and J. Namiesnik. 2002. Sampling selective solid materials, Chapter 3. In: J. Pawliszyn (ed.), Sampling and Sample Preparation for Field and Laboratory. Fundamentals and New Directions in Sample Preparation, pp. 61–86. Elsevier, Amsterdam. 49. USEPA. Sampling for contaminants in sediments and sediment pore water, measurement and monitoring technologies for the 21st Century [21M2]. Available at http://www.clu-in.org/programs/21m2/sediment/ default.cfm. 50. Ohio, E.P.A. 2001. Sediment Sampling Guide and Methodologies, 2nd edition. Available at http://www. epa.state.oh.us/dsw/guidance/sedman2001.pdf. 51. Punning, M.J., T. Alliksaar, J. Terasmaa, and S. Jevrejeva. 2004. Recent patterns of sediment accumulation in a small closed eutrophic lake revealed by the sediment records. Hydrobiologia 529: 71–81. 52. Ricking, M., J. Schwarzbauer, and S. Franke. 2003. Molecular markers of anthropogenic activity in sediments of the Havel and Spree Rivers (Germany). Water Res. 37: 2607–2617. 53. Schwarzbauer, J., M. Ricking, S. Franke, and W. Francke. 2001. Halogenated organic contaminants in sediments of the Havel and Spree Rivers (Germany). Part 5 of organic compounds as contaminants of the Elbe River and its tributaries. Environ. Sci. Technol. 35: 4015–4025.

2

Preservation and Storage of Water Samples Marek Biziuk, Angelika Beyer, and Joanna Z·ukowska

CONTENTS 2.1 2.2 2.3

Introduction ........................................................................................................................ Preservation of Water Samples for the Determination of Inorganic Compounds .............. Preservation of Water Samples for the Speciation Analysis of Metals .............................. 2.3.1 Arsenic .................................................................................................................... 2.3.2 Chromium ............................................................................................................... 2.3.3 Mercury .................................................................................................................. 2.3.4 Selenium ................................................................................................................. 2.3.5 Tin ........................................................................................................................... 2.4 Preservation and Storage of Water Samples for the Determination of Organic Compounds ....................................................................................................... 2.5 Summary ............................................................................................................................ Acronyms and Abbreviations ....................................................................................................... References ....................................................................................................................................

19 19 22 25 26 26 26 27 27 33 33 33

2.1 INTRODUCTION Accurate determinations of the numerous parameters and components in water samples are essential in many research programs. Nevertheless, no matter how accurate and sensitive the analytical devices and techniques applied during the analysis, the data will be useless unless special attention is given to counteracting the potential changes proceeding within a sample. A large number of substances contained in water can be expected to undergo various chemical, physical, and biological transformations. Such processes can alter the sample composition and consequently lead to unrepresentative results. Sample preservation is therefore necessary in order to inhibit reactions in the sample during the period between sampling and analysis. Unfortunately, analysis of water samples at the point of sample collection is often not possible, so sample preservation is imperative. A wide variety of techniques are therefore applied to minimize loss of target compounds from water samples during the sample holding time (Figure 2.1).

2.2 PRESERVATION OF WATER SAMPLES FOR THE DETERMINATION OF INORGANIC COMPOUNDS The determination of inorganic compounds in water samples provides significant data for risk assessment in aquatic environments and for characterizing the chemical quality of water. The presence of inorganic chemicals in water is due to both natural processes and human activities. Most of these 19

20

Analytical Measurements in Aquatic Environments

Chemical methods Addition of: • Acid, • Sulfite, • Solvent, • Toxic metal ions, • Azide, • Formaldehyde, • Other substances.

FIGURE 2.1

Physical methods • Cold storage, • Frozen storage, • Dark storage, • Use of amber bottels (or other special types of bottles), • Filtration, • Collection of the sample without headspace, • Collection of the sample without changing oxidation-reduction (redox) conditions, • Real-time or nearly real-time isolation of the chemicals using LLE, SPE, or SPME, • Using coacervates.

Methods used to minimize loss of inorganic and organic chemicals from water samples.

compounds are water soluble, and they may be responsible for many disorders occurring in living organisms. The monitoring of water quality is thus of paramount importance. To control the levels of target compounds, accurate measurement is indispensable, and hence, sample contamination or degradation prior to analysis must be minimized. To this end, the establishment of a control program for assessing contamination risks at each stage in the analytical process is of crucial significance. The containers used for transporting and storing water (intended for the determination of inorganic components) have to be carefully selected and cleaned to minimize the risk of possible contamination. The usual materials from which these containers are made include high-density polyethene (HDPE), polypropene (PP), fluorinated ethene propene copolymer (FEP), perfluoroalkoxy polymer (PFA), poly(tetrafluoroethene) (PTFE), or glass (e.g., Pyrex borosilicate glass).1-6 When sample bottles are being selected, the type of analyte being measured, the conditions of preservation, and the physical characteristics of the container should be taken into consideration. In general, the storage of water samples for the determination of inorganic components should be avoided if at all possible.7 Nevertheless, the nature of the research and the lack of adequate equipment required for further analysis may preclude the immediate determination of the compounds in question. It is therefore of great interest to explore appropriate preservation and storage methods that enable unfavorable sample changes to be minimized. Maintaining the original sample composition until the analysis can be performed is the absolute requirement for successful preservation. Beyond this, there are many other factors that should be considered, such as compatibility with the analytical technique to be used for the final determination, simplicity, rapidity of implementation, and so on.8,9 Numerous approaches, both physical and chemical, are recommended in the literature for the preservation of water samples for inorganic chemicals analysis. In particular, the significance of freezing, pasteurization, as well as the use of chemical preservatives such as acids, sodium hydroxide, chloroform, formaldehyde, or mercuric chloride as alternative techniques has been emphasized.8,10 Table 2.1 describes some recommended stabilization methods. The large majority of known stabilization procedures are based on relatively few parameters, the most important of which are temperature, pH, and redox potential. Despite the different treatments, the final aim of these efforts is the same: All preservation processes are intended to (1) inhibit the growth and biological activity of microorganisms, a unique source of concentration changes of dissolved inorganic components; (2) diminish the volatility of sample components; (3) retard hydrolysis reactions, precipitation, and coprecipitation reactions; and (4) reduce absorption effects.11,12 Unfortunately, there is no single, universal procedure applicable to the stabilization of all compounds (Table 2.2). The choice of procedure is therefore dependent primarily on factors relevant to the sample in question (e.g., salinity and dissolved chemical compounds), type of analyte, environmental impact of the method, and the particular preservation situation (e.g., costs and periods of storage).

21

Preservation and Storage of Water Samples

TABLE 2.1 Advantages and Disadvantages of Selected Preservation Methods Used for Water Samples10,13–17 Water Preservation Methods

Advantage

Disadvantage

Physical Freezing

Pasteurization

• No change of the sample matrix, and in consequence elimination of potential risk of contamination due to added chemicals • No risk connected with exposure to toxic substances • An alternative method for long-term sample storage • Causes the reduction of the activity of microorganisms present in the sample • Possibility of storage samples at room temperature over long periods

• Necessity of maintenance of low temperature storage • Risk of losing the sample in the case of equipment failure • Possibility of occurrence of considerable variability in amount of compounds arising from the matrix, adsorption on suspended matter presented in the sample, formation of suspended matter during freezing, and adsorption on the vessel walls • Possibility of precipitation of colloids • Necessity of using a special sample bottles selected for their cap tightness and pressure resistance

• Enables the long-term stabilization of inorganic compounds

• Risk of sample contamination and additional interference during analyses • Anions of acids may be a source of interference for the analytical method • Some of the poisons can hydrolyze organic compounds during storage or precipitate bacteria and proteins

Chemical Addition of poisons (biocides)

TABLE 2.2 Examples of Preservation Methods of Water and Wastewater Samples for the Determination of Inorganic Compounds Type of Compound Ammonium nitrogen, free and ionized ammonia Ammoniacal nitrogen, oxidized nitrogen

Type of Preservation Cooling to 2–6°C

Maximum Holding Time 6h

Acidification to pH < 2 with H2SO4

28 days

Storage on water ice

6h 6h

Acidification to pH < 2 with H2SO4 Immediate freezing with dry ice and then stored in laboratory freezer Prolonged refrigeration Pasteurization and stored at room temperature

Reference International Organization for Standardization (ISO) EPA 18

24 h 54 h 18 months

19 continued

22

Analytical Measurements in Aquatic Environments

TABLE 2.2

(continued)

Type of Compound Kjeldahl nitrogen

Type of Preservation Cooling to 2–6°C Acidification to pH < 2 with H2SO4 Storage on water ice Immediate freezing with dry ice and then stored in laboratory freezer Prolonged refrigeration

Nitrate

Cooling to 2–6°C Acidification to pH < 2 with H2SO4

Total phosphorus (TP) and filterable reactive phosphorus (FRP) TP

Frozen at −40°C initially and then stored at -20°C Addition of mercuric chloride Storage on water ice Immediate freezing with dry ice and then stored in laboratory freezer Prolonged refrigeration Acidification to pH < 2 with H2SO4 and stored at room temperature Acidification to pH < 2 with H2SO4 and stored at 4°C Pasteurization and stored at room temperature

FRP

Maximum Holding Time 6h 28 days 6h 6h 24 h

Reference ISO EPA 18

54 h 48 h 28 days

EPA EPA

24 months

20

26 months 6h 24 h

10 18

54 h 7 days

21

28 days

Frozen at −16°C

18 months 4–8 years

11 22

Metals

Acidification to pH < 2 with HNO3

6 months

Nonionic surfactants Silicate Sulfide

Addition of formaldehyde Addition of mercuric chloride Addition of cadmium acetate or zinc acetate Addition of sodium hydroxide to pH > 12 Cooling to 2–6°C

48 h 26 months 7 days 28 days

American Public Health Association (APHA), ISO, EPA, ISO 10 EPA APHA

28 days

EPA

Addition of sodium hydroxide to pH > 12

14 days

EPA

Bromide, chlorine, chloride, fluoride Iodine

2.3

PRESERVATION OF WATER SAMPLES FOR THE SPECIATION ANALYSIS OF METALS

The preservation of chemical compounds, especially the individual chemical species in a sample, is an important consideration in analysis. At present, much effort is going into the search for effective procedures to prevent quantities and species of elements in their original state from undergoing chemical, biochemical, and photochemical changes. Arsenic, chromium, mercury, selenium, and tin have been the object of numerous investigations. Because some of them are classified as probable human carcinogens23-25 (strictly speaking, some of their species), the accurate assessment of concentration and speciation in environmental matrices is enormously important. Unfortunately, such factors as chemical reactions between species, low concentration, microbial activity, redox conditions, as well as the presence of other dissolved metal ions, may cause the amounts and distributions of chemical species in a sample to vary. In response to these problems, analytical research efforts have focused on developing techniques enabling the original valence state of the metals to be preserved. Table 2.3 lists some of these stabilization methods.

23

Preservation and Storage of Water Samples

TABLE 2.3 Some Characteristics of Storage Methods for the Speciation Analysis in Water Samples Type of Compound As(III), As(V)

Type of Sample Seepage water (rich in Fe and Mn) Well water (rich in Fe and Mn) Acid mine waters Synthetic groundwater without Fe (pH 8.4) Synthetic groundwater with Fe(II) (pH 8.4) Drinking waters

Total dissolved As and As(III)

As(III)

As(V)

Cr(III), Cr(VI)

−1

The acidification to pH ≤ 2 with 0.01 mol L H3PO4 and cooling to a temperature of 6°C, storing in darkness The addition of ethylenediaminetetraacetic acid (EDTA) The addition of EDTA The addition of H2SO4, H3PO4, and preservative reagent EDTA-HAc and stored in brown PP bottles at room H2SO4 and EDTAtemperature HAc (22–24°C) H3PO4 EDTA-HAc

Reference

3 months

26

14–27 days

27

3 months 7 days

28 29

28 days 7 days >30 days

Groundwater samples (with neutral pH and poor in Fe)

Without any treatment

£3 days

The acidification with phosphoric acid and storage at 4°C

>3 days

Seepage water (rich in Fe and Mn)

The acidification with 0.01 mol L−1 H3PO4 and storage at 6°C Without preservation Dark experiment Light experiment The addition of HCl Dark experiment Light experiment The addition of HCl, Dark experiment Fe(II), and SO4

6 days

31

16 days

32

Synthetic, doubledistilled water (pH 3.7) Synthetic water with Fe(III) Natural waters Geothermal and acid mine waters Deionized water spiking with 40 mg As(V) Aqueous reference material Aqueous sample

Cr(VI)

Maximum Holding Time

Type of Preservation and Storage of Samples, and Main Parameters

Coastal seawater Oceanic water Water sample

30

45 days 71 days

Filtration, acidification to pH < 2 with HCl, chilled at 4°C, and stored in the dark Filtration, acidification with HCl and stored in opaque bottles The storage in dark at 4°C in polyethylene (PE) containers

—

67 days

33

The setting pH to 6.4 by HCO3−/H2CO3 buffer and storage at 5°C in quartz ampoules Freeze-drying, stored at −20°C and later reconstituted in HCO3/H2CO3 buffer (pH 6.4) under a CO2 blanket The storage at room temperature and at natural pH Deep freezing The storage of samples at a temperature of 4°C

228 days

34

88 days

35

1 month

36

8 months 24 h

37, 38

19 months

continued

24

TABLE 2.3

Analytical Measurements in Aquatic Environments

(continued)

Type of Compound Cr(III)

Type of Sample Water sample

Cr(IV) Total Hg

Freshwater and seawater

Methyl-Hg

Freshwater

Dimethyl-Hg and Hg(0) Hg(II)

Dissolved/ particulate speciation Dissolved inorganic and labile Hg Inorganic and methyl-Hg

Total Hg

Estuarine water

River water

Water sample

Total and methyl-Hg

Se(IV), Se(VI)

Natural and distilled water

Type of Preservation and Storage of Samples, and Main Parameters The collection of The addition of 1 mL samples into 500 mL chromium (III) or 1 L fluoropolymer, extraction solution conventional or linear to 100 mL aliquot, PE, polycarbonate vacuum filtration (PC), or PP containers through 0.4 μm with lid membrane, and the addition of 1 mL 10% HNO3 The addition of 50% NaOH The collection of samples into a glass (with PTFE-lined lid) or PTFE bottles prerinsed with acid, and the addition of BrCl or 0.5% HCl The collection of filtered samples into a glass (with PTFE-lined lid) or PTFE bottles prerinsed with acid, and storage in the dark at 1–4°C The acidification with 0.5% HCl or 0.2% H2SO4 and storage in the dark at 1–4°C The collection of unfiltered samples into a glass (with PTFE-lined lid) bottles and storage in the dark at 1–4°C The collection of filtered samples into a glass (with PTFE-lined lid) bottles and storage in the dark at 1–4°C The collection of samples into a glass (with PTFE-lined lid) or PTFE bottles and storage in the dark at 1–4°C The collection of unfiltered samples into a glass container and addition of 1% HNO3 Trapping in minicolumn packed with C18 modified with diethyldithiocarbamate and elution with 500 mL of 5% thiourea in 0.5% HCl The collection of The acidification to samples into pH > 2 with 0.5% fluoropolymer or high-purity HCl or borosilicate glass 0.5% BrCl bottles with The addition of 0.5% fluoropolymer or high-purity HCl fluoropolymer-lined caps The acidification to pH 1.5 with H2SO4 and storage in PE or Pyrex containers at room temperature

Maximum Holding Time

Reference

–—

39

300 days

40

1 week

250 days 1 day

2–5 days

2–5 days

30 days

41

1 week

42

–—

39

–—

4 months

43

continued

25

Preservation and Storage of Water Samples

TABLE 2.3

(continued)

Type of Compound Total Se and Se(IV) SeCys, SeMet, TMSe

Se(IV), Se(VI), SeMet Tributyltin chloride (TBT), triphenyltin chloride (TPhT) TPhT

Type of Sample Seawater Aqueous matrix

Aqueous mixtures River water Aquatic solution Seawater

TBT

Organotin compounds

Water samples

Type of Preservation and Storage of Samples, and Main Parameters

Maximum Holding Time

Reference

The acidification to pH 2 with HCl and storage in PE or glass containers The storage in the dark at pH 4.5 in Pyrex containers at both 4°C and 20°C The storage in the dark at 4°C in PP containers The storage at 3°C

4.5 months

44

1 year

45

6 weeks

46

2 weeks

47

The acidification to pH 4 with HNO3 and storage in PE containers at 4°C in the dark The acidification with HCl and storage in PE containers at 4°C in the dark Storage on C18 cartridges at room temperature The storage in the dark at 4°C in PC bottles or storage on C18 cartridges at room temperature. The storage in 1-L brown glass bottles at 25°C

1 month

48

3 months

49

60 days

50

7 months

20 days

51

Filtration, acidification, chilling, and freezing are some of the numerous techniques for preserving inorganic species in water samples. Depending on the species of the target chemical element, however, the stabilization conditions may vary from one type of sample to another (see Table 2.3).

2.3.1

ARSENIC

The presence of high levels of arsenic in aquatic ecosystems is a consequence, firstly, of the weathering of arsenic-containing rocks and soils, and secondly, of rapid industrial growth, the intensive use of agricultural chemicals, and the urban activities of human beings, such as irresponsible sewage and waste disposal. In natural waters, arsenic is primarily present as trivalent arsenite As(III) and pentavalent arsenate As(V),52 the former being more toxic and more mobile than the latter.53 Because of the strong tendency for arsenic compounds to undergo changes, every effort should be made to preserve As(III)/As(V) speciation in water samples. The most frequently used pretreatment procedures for stabilizing arsenic species include filtration, acidification with inter alia sulfuric, phosphoric, or hydrochloric acids,28,31,54 and the addition of a complexing agent such as EDTA;55 all these procedures are carried out under controlled temperature and light conditions. Recent experiments on the effect of UV radiation on the stability of arsenic species in the presence of Fe(II) have shown that oxidation of As(III) to As(V) depends strongly on UV exposure. Samples should therefore be stored in the dark or in opaque propylene bottles until analysis.29 Moreover, many researchers have reported problems with the preservation of arsenic species in iron-rich waters. Gallagher et al.27 recommend preserving iron-rich water samples at a lower pH. In contrast, Bednar et al.28 state that using EDTA without lowering the pH is sufficient to preserve As species. Several studies have shown that nitric acid can preserve As species from oxidation of As(III) to As(V).28,56 Fanning,57 however, reports that nitric acid is an oxidizing agent capable of undergoing photochemical reduction and should not be used to preserve redox species.

26

2.3.2

Analytical Measurements in Aquatic Environments

CHROMIUM

Chromium enters surface waters from natural sources, such as the weathering of rock and the wet precipitation and dry fallout from the atmosphere, as well as from the extensive use of this metal in, for example, chemical, metallurgical, and refractory industries.58 The unsatisfactory disposal of industrial wastes also contributes to the presence of this element in the environment. Chromium can exist in several chemical forms, but only two of them—trivalent Cr(III) and hexavalent Cr(VI)—are stable enough to occur in the environment. Cr(VI) is approximately 100 times more toxic than Cr(III);59 unfortunately, its compounds are usually highly soluble, mobile, and bioavailable compared to those of Cr(III). The accurate determination of each of these species is thus of the utmost importance, especially as regards the proper evaluation of physiological and toxicological effects. Water samples should be subjected to an appropriate preservation treatment that prevents species degradation and interconversion. For chromium species, refrigeration, minimal sample handling, and immediate analysis of water samples are generally preferable.60,61 However, should long-term storage be unavoidable, it is enough to freeze the sample for chromium compounds to remain stable.58 The Cr(III)/Cr(VI) ratio can also be preserved if the sample is stored at pH 9; under such conditions, the oxidizing potential of Cr(VI) is too low to oxidize reducers present in natural water.62 The ratio can also be upheld at a nearly neutral pH, particularly under a CO2 blanket.36,63 Acid media should not, however, be used to preserve chromium species, since under such conditions Cr(VI) will undergo rapid reduction to Cr(III).

2.3.3

MERCURY

Mercury is one of the most dangerous water pollutants because of its accumulative and persistent character in the environment.64 The impacts of volcanic activity, as well as the mining and smelting of mercury and other metal sulfide ores, fossil fuel combustion, and industrial processes involving the use of mercury are considered to be of the greatest magnitude.65 It is well known that the reactivity and toxicity of Hg depends to a large extent on the species. All forms of mercury are poisonous,66 but its organic forms (methyl and dimethyl mercury) exhibit the greatest toxicity. The efficiency of techniques for minimizing potential transformation and degradation processes need to be improved continually. The material from which a sample container is made may give rise to major changes in mercury speciation.4,67,68 Yu and Yan69 reviewed the application of various bottle samples, focusing particularly on improving the stability of mercury species during sample storage. Generally, PTFE and glass bottles are recommended; containers made from PE should not be used to store water samples with low levels of mercury as this material is permeable to mercury vapor from the atmosphere.41 The most common means of preserving Hg species include acidification with strong mineral acids (HCl, H2SO4, and HNO3) and the addition of oxidizing (KMnO4, K2Cr2O7, H2O2, or Au3+) or complexing agents (Cl-, I-, Br -, CN-, l-cysteine, and humic acid).67,70-72 Nevertheless, although acidification with HCl works well for preserving both total and methyl mercury, this type of stabilization is not suitable for labile Hg(II) because of the possible dramatic loss to the container walls and oxidation of Hg(0) to Hg(II).40 Furthermore, it seems inadvisable to use HNO3 as a preservative for methyl mercury as this form of the metal may decompose, especially in the presence of halides.40 Thus, no ideal method has been found for stabilizing all the original valence states of mercury in water samples.

2.3.4

SELENIUM

A contaminant of concern, selenium enters aquatic ecosystems from natural sources, and from anthropogenic ones such as coal mining and combustion, gold, silver, and nickel mining, metal smelting, oil transport, the utilization and refining of crude oil, municipal landfills, and agricultural irrigation.73 In recent decades, considerable research effort has focused on selenium, the reason being the narrow margin between its toxicity and its role as an essential element in the human

Preservation and Storage of Water Samples

27

organism. Both organic (mainly as amino acids or volatile methylated compounds) and inorganic species (in the oxidation states—II, 0, IV, and VI)74 of Se are present in the environment, each species with different toxicological properties. In general, inorganic forms are considerably more toxic than organic ones, and selenium (IV) is considerably more toxic than selenium (VI).75 In view of the above, analysts should strive to achieve greater accuracy in the determination of selenium species. There are numerous reports on the preservation of selenium species; the significance as regards selenium stabilization in an aqueous medium of parameters such as pH, storage medium, temperature, and container material is discussed in a number of articles.76,77 In aqueous solution selenium (VI) is generally more stable than selenium (IV), and is not so sensitive to the pH of the sample.78 According to Héninger et al.,76 aqueous samples containing selenium species are best stored in HCl in PTFE containers at 4°C.

2.3.5

TIN

As in the case of the elements mentioned above, the toxicity of tin compounds to living organisms depends largely on the oxidation state of the metal. Generally, the organic species are significantly more toxic than the inorganic ones, and trisubstituted organotins (TBTs) (especially butyl and phenyl species) are considered more toxic than the corresponding mono-, di-, or tetrasubstituted compounds.79-81 The European Parliamentary Commission has included TBTs in the European list of most hazardous substances.82 Because of their numerous applications in various sectors of industry,83 and consequently, the real risks to the environment and human health from organotin exposure, the European Community has imposed the obligation to monitor the TBT content in aquatic environments.84-86 Hence, their persistence and concentration are determined in many environmental matrices. Nevertheless, with regard to the quantitative speciation of tin compounds, a special effort should be made to gaining an understanding of the reactions occurring during the storage of water samples containing different tin species, for example, the activity of microorganisms, and changes in oxidation states and sorption. In order to prevent changes to the initial sample composition, a variety of preservation techniques have been put forward (Table 2.3). Burns et al.87 recommend that for reliable results of speciation analysis, samples should be frozen and analyzed within the shortest possible time.

2.4 PRESERVATION AND STORAGE OF WATER SAMPLES FOR THE DETERMINATION OF ORGANIC COMPOUNDS Water pollution by organic compounds, many of which are known to be toxic and carcinogenic, has given rise to considerable concern worldwide.88 That is why water samples should be treated appropriately in order to prevent changes to particular sample components. It is essential that both the identity and the concentration of the target organic compounds in water samples remain the same from sample collection to analyte determination. Minimizing change in and loss of target organic chemicals from water samples is important to the integrity of an investigation.89 Organic chemicals can be lost from water samples through volatilization, sorption, and conversion reactions. Volatilization can remove chemicals from the water phase to the air space in an unfilled bottle (headspace), sorption can remove them from the water to the walls and cap of the sample bottle, and conversion reactions can eliminate them from the water altogether. Conversions of possible concern are anaerobic or aerobic biodegradation, photolysis, abiotic hydrolysis, and abiotic redox reactions.89 The analytical procedures for determining organic compounds in water samples usually involve a number of steps, such as solvent extraction, chemical fractionation, sample cleanup, and solvent reduction, before the final analysis is undertaken. Regardless of the complexity of the analytical procedure, however, almost all water samples are stored in a container for some time between

28

Analytical Measurements in Aquatic Environments

sample collection (or isolation of the organic compounds from the water) and final analysis, unless they are isolated in real time during collection.89 Organic compounds are the most common anthropogenic water pollutants,8 and industrial, domestic, and agricultural wastewaters are major sources of water contamination with these substances. A variety of techniques for preserving and storing water samples containing organic compounds can be applied; which one is chosen depends mainly on the target chemical. The organic compounds most frequently found in water and wastewater samples are • • • • • •

Pesticides Phenols Aliphatic and aromatic hydrocarbons Polynuclear aromatic hydrocarbons (PAHs) Surfactants Halogen compounds.

Pesticides come under the headings of both organic and inorganic compounds. Because of their different chemical and physical properties, they have been divided into groups—the inorganic, botanical, and synthetic organic pesticides.90,91 The four basic types of synthetic organic pesticides are the chlorinated hydrocarbons, organophosphates, carbamates, and pyrethroids. The stability of pesticides from different groups has already been studied in order to specify the conditions of transport or temporary storage of samples before their analysis. To stabilize samples containing pesticides, different agents, such as pH modifiers, chelating agents, or microbial inhibitors can be used; a reduced temperature may also be applied.92 In such a diverse group as pesticides, however, the agent required to stabilize certain compounds in the sample may affect the stability of others. By way of example, Ferrer and Barcelo93 demonstrated that acidification may damage certain pesticides such as fenamiphos, whereas other compounds such as fenitrothion can only be kept stable in an acidic medium. Also, water samples containing acidic herbicides are usually acidified for preservation, and then stored at 4°C prior to extraction and analysis.94 Table 2.4 lists some of the most commonly used recommendations for determining pesticides in water. Like pesticides, phenols turn up in aquatic environments quite frequently because of their wide application in the chemical industry. The largest single use of phenol is in the manufacture of plastics, but it is also used in the synthesis of caprolactam (for making nylon 6 and other man-made fibers) and bisphenol A (for producing epoxy and other resins). Further uses are as a slimicide (a chemical that kills the bacteria and fungi found in aquatic slimes), as a disinfectant, and in medical products.95 Because of their toxicity and environmental persistence, a number of phenols have been targeted by different monitoring programs, such as those of the US Environmental Protection Agency (EPA) and of the European Union (EU).96 According to EPA instructions, water samples containing phenols must be extracted within seven days of collection and completely analyzed within 40 days of extraction.97 Acidification is frequently recommended to preserve water samples for phenols determination (see Table 2.4). Polychlorinated biphenyls (PCBs) have entered the natural environment via human agencies. The risks posed by their presence in the environment are a direct consequence of their physicochemical properties—good solubility in nonpolar solvents, oils and fats, low vapor pressure, low electrical conductivity, high thermal conductivity, high ignition temperature, and very high resistance to chemical factors. These favorable properties are the reason for their wide application in industry.98–100 EPA instructions state that if samples containing PCBs and organochlorine pesticides are not extracted within 72 h of collection, the pH of the sample should be adjusted to 5.0–9.0 with sodium hydroxide solution or sulfuric acid.101 Water samples containing PCBs should be stored in amber glass containers, restricting the access of light, and preserved by freezing (see Table 2.4). PAHs, a large group of organic compounds, have received considerable attention, since several of them have been shown to elicit carcinogenic and teratogenic reactions in experimental animals. Environmentally significant PAHs, from naphthalene to coronene,88 are ubiquitous

29

Preservation and Storage of Water Samples

TABLE 2.4 Methods for the Preservation of Water and Wastewater Samples for the Determination of Organic Compounds

Type of Compound

Type of Preservation and Storage of Samples, and Main Parameters

Maximum Holding Time or Time of Experiment

Reference

Pesticides Pesticides Chloroorganic and phosphoroorganic pesticides, and derivatives of phenoxyacetic acid Organophosphorus insecticides in surface water Different group of polar pesticides in surface and tap water Organophosphorus pesticides

Carbamate pesticides

Herbicides, organochlorine, and organophosphoric insecticides Diquat and paraquat

Phenols

PCBs

The addition of extracting solvent and cooling to a temperature 2–5°C The addition of mercury chloride (1 mL solution of 10 mg (mL)–1 concentration per 1 L sample)

Depends on the solvent used 40 days

102

Trapping in large-particle-size graphitized carbon black cartridges and keeping at −20°C

2 months (recoveries approaching 70–134%)

104

Trapping in SPE cartridges packed with polymeric material and stored at 4–5°C or at laboratory temperature (no substantial differences) Trapping in SPE cartridges filled with C18 and stored at −20°C Trapping in SPE cartridges filled with C18 and stored at 4°C Trapping in SPE cartridges filled with C18 and stored at laboratory temperature The addition of sodium thiosulfate and monochloroacetic acid, cooling to a temperature of 4°C in amber vials The collection of samples in glass bottles prerinsed with acetone and hexane, the addition of 1 mL of HgCl2 1% for preservation, storage at <10°C

7 weeks

105

8 months

106

2 months 1 month 28 days

107

7 days (than extraction), after extraction 14–28 days

108

109

The acidification with sulfuric acid to pH < 2, addition of sodium thiosulfate and cooling to 4°C The acidification with sulfuric acid to pH < 2, frozen, and stored in glass container The acidification with phosphoric acid to pH < 4, frozen, and stored in glass container Trapping in SPE cartridges packed with polymeric material (Isolute ENV+) and stored at −20°C Trapping in SPE cartridges packed with polymeric material (Isolute ENV+) and stored at 4°C The preservation mostly through freezing, storing in amber glass containers, restricting the access of light The collection of samples in Pyrex borosilicate amber glass containers with caps lined with aluminum foil and storage in the dark at 4°C

103

3–4 weeks

110,111 102

2 months

96

0.5 month

7 days

112

48 h

EPA

continued

30

TABLE 2.4

Analytical Measurements in Aquatic Environments

(continued)

Type of Compound PAHs

Aliphatic hydrocarbons

VOCs

Type of Preservation and Storage of Samples, and Main Parameters

Nonionic surfactants

Low-molecular-weight organic acids

Dissolved organic carbon

Reference

Storage of samples at a temperature of 4°C in amber or foil-wrapped bottles The addition of 1.0% SDSA and storing in glass containers

7 days

113

4 days—recovery values near to 100%

114

Storage of solvent extracts or sorption tubes with analytes trapped, in freezer in glass vials closed with PTFE stoppers Trapping in SPE phases, XAD-2 macroreticular resin and C18 and stored at room temperature Cooling to 4°C and the acidification with HCl to pH < 2

1 month

115,116

100 days

117

14 days if preserved with HCl, 7 days without HCl 112 days

118

96 h (time of experiment) There is no demonstrated maximum holding time, up to 1 year 20 days 6 days

120

The acidification with sodium bisulfate or ascorbic acid, storing at 4°C Storage of samples at a temperature of 4°C Dioxines and furanes

Maximum Holding Time or Time of Experiment

Addition of sodium thiosulfate (if residual chlorine is present), cooling to 0–4°C, storage in the dark Addition of formaline in concentration 1% Addition of formaldehyde in concentration 0.1% Addition of mercury (II) (25 mg L–1) or copper (II) (50 mg L–1) Addition of chloroform together with refrigeration of a sample (4°C) Dried ethyl acetate extracts of sewage samples mixed with chloroform (1:2) Freezing Sterile filtration Sterile filtration in combination with storage of the samples (natural waters) in the dark at 4°C Storage of samples (rainwater) at a temperature of 4°C The acidification with H3PO4 and storage at 4°C

119

121

122

6 days 6 days 28 months

123

4 weeks 1 day

124

<30 days

1 week

125

15 months

126

pollutants formed, inter alia, from the combustion of fossil fuels; they are always present as a mixture of individual compounds. Because many PAHs and their derivatives are so dangerous, the source, occurrence, transport, and fate of PAHs in waters have been extensively studied.88,127,128 According to the literature, the main factor affecting the stability of PAHs in waters is their adsorption to containers.129,130 This problem can be overcome by using containers made from appropriate materials, by acidifying the water sample, or by adding acetonitrile

Preservation and Storage of Water Samples

31

at concentrations between 25% and 40% (v/v);131 it should be noted, however, that these strategies are only successful in the very short term. Generally, samples must be frozen or refrigerated at 4°C from the time of collection until extraction. Because PAHs are light sensitive, samples and extracts should be stored in amber glass or foil-wrapped bottles to minimize photolytic decomposition.123 Table 2.4 summarizes these and other appropriate preservation methods. Water (especially drinking water) containing high levels of volatile organic compounds (VOCs) can also be harmful to human health because of their physical and chemical properties and biological effects. VOCs consist of aromatic and chlorinated compounds with boiling points below 200°C and are one of the classes of compounds most frequently found at hazardous waste sites. They are carcinogenic and/or mutagenic, even at low concentrations, and are environmentally persistent. Generally, for the determination of VOCs it is recommended to fill the sample storage container completely and then to freeze it (UKSCA).120 In the case of dihaloacetonitriles, which are the most common class of volatile chlorination by-products after trihalomethanes, practically no decomposition took place during the storage period (96 days at 4°C).132 For further recommendations, see Table 2.4. Determination of noninorganic surfactants (NS) in environmental water samples or in samples relevant to environmental water quality (sewage, processing liquors in sewage treatment plants, and treated sewage) is difficult because of the complexity of the matrix, the multicomponent nature of the NS mixture in the aquatic environment, and the limited stability of samples.133 Natural waters also contain a wide range of low-molecular-weight organic molecules (LMWOM), which are regarded as products of the microbial decomposition of, primarily, plant matter; some have even been used as identifiers for certain genera of decomposers.123,124 Water samples can contain different organic contaminants that are known to be toxic and/or carcinogenic even at low concentrations (see Table 2.4). That is why it is so important to maintain vigilance and control of pollution in the aquatic environment to ensure that water quality standards are met. Organic pollutants occur in low concentrations, so large volumes of water usually have to be sampled if suitable detection limits are to be achieved after an appropriate preconcentration step. As a result, the reduction in effort and costs of transporting and preserving such high-volume samples has become an important topic, especially in environmental monitoring programs.134 For this reason, it is the concentrates of organic analytes following separation and enrichment rather than the original high-volume water samples that are stored. Among the numerous techniques for separating and enriching organic compounds from water samples, the following are worthy of mention: solid-phase extraction (SPE), solid-phase microextraction (SPME), liquid–liquid extraction (LLE), and lyophilization. SPE with a variety of sorbents is an effective sample handling method for the analysis of organic compounds in water.135 It is used to extract compounds directly in the field for the shortterm storage of analytes, thereby enabling the transfer of samples to the laboratory for analysis.136 Other studies have investigated the storage of different groups of pesticides on a C18 silica precolumn,137,138 polymeric sorbents,93,139 or graphitized carbon black sorbents.104 Fenitrothion (an organophosphorus pesticide), for example, was preconcentrated on a XAD-2 column, after which the samples remained stable for five weeks at room temperature.140 Green and Le Pape117 examined two solid phases—XAD-2 macroreticular resin and octadecane bonded to silica gel—and demonstrated the stability of hydrocarbons sorbed from water onto these types of solid phases. Hydrocarbons stored on these solid phases for periods of up to 100 days in the presence of an oleophilic bacterial population showed no evidence of biological degradation. In contrast, hydrocarbons stored in water samples containing the same bacteria showed pronounced degradation over much shorter storage periods. In the last few years a variety of sorbents have been proposed for the preservation of organic compounds (see Table 2.4). Figure 2.2 presents the advantages of SPE as a handling technique.

32

Analytical Measurements in Aquatic Environments

Advantages

• The prevention from deccomposing the analytes’ sorbed onto the SPE column • The possibility of storage for a certain period of time without a change in concentration or identity • Much more convenient transport of SPE cartridges than transport of bulky glass containers • A variety of sorbents • A possibility of usage in the field, in this way extraction is done in situ and the collection of the water itself is avoided • A possibility of simultaneous extraction and preconcentration of the target compounds

The minimization of the danger of alteration of the sample between in-the-field sampling and analysis in the laboratory

FIGURE 2.2 SPE as an effective sample handling method.105,134

SPME, a variant of SPE, involves the adsorption of organic pollutants from the matrix onto the solid-phase coating. The adsorbed analytes are then directly transferred to a gas chromatography (GC) injector using a modified syringe assembly or can be stored for a certain period of time.141 LLE has traditionally been used to separate and concentrate organic compounds from water samples. Because this technique has many drawbacks, there has been a general trend to replace LLE with SPE protocols.141 A quite novel approach to the preservation of organic compounds in water samples is the use of coacervates. These are water-immiscible liquid phases produced in colloidal solutions by the action of a dehydrating agent (e.g., changes in the temperature or pH of the solution, addition of an electrolyte, or addition of a water-miscible solvent in which the macromolecule is poorly soluble).142 Luque et al.117 studied the ability of coacervates to preserve organic compounds in order to determine their applicability for the extraction/preconcentration/preservation of pollutants in environmental monitoring programs. For this purpose, anionic micelle-based coacervates were used. The target pollutants were benzalkonium surfactants and polycyclic aromatic hydrocarbons, because of the instability problems they present in environmental water samples. Their stability in coacervates was investigated for a period of three months under different experimental conditions (Figure 2.3).

The preconcentration factor does not depend on the sample volume but on the surfactant concentration, so we can treat low sample volumes which make sample handling easy

The extraction is simple and rapid

COACERVATES

Only low cost equipment is required

The low volume of coacervates permits to store them in vials which facilitate trasport and storage

FIGURE 2.3

Advantages of using coacervates for the preservation of organic compounds.134

Preservation and Storage of Water Samples

2.5

33

SUMMARY

Samples should be collected, transported, and stored in such a way that they remain in unchanged form until they are subjected to final analysis. A thorough knowledge of the conditions of sample preservation and storage for the determination of the compounds in question is therefore essential. Numerous approaches, both physical and chemical, are recommended in the literature for the preservation of water samples prior to the analysis of inorganic and organic chemicals. Unfortunately, none of these methods is able to prevent analyte loss from different kinds of water matrices.

ACRONYMS AND ABBREVIATIONS APHA ASTM EDTA EPA EU FEP FRP GC HDPE ISO LLE LMWOM NS PAHs PC PCBs PE PFA PP PTFE SPE SPME TBT TP TPhT VOCs

American Public Health Association American Society for Testing and Materials ethylenediaminetetraacetic acid Environmental Protection Agency European Union fluorinated ethene propene copolymer filterable reactive phosphorus gas chromatography high-density polyethene International Organization for Standardization liquid–liquid extraction low-molecular-weight organic molecules noninorganic surfactants polynuclear aromatic hydrocarbons polycarbonate polychlorinated biphenyls polyethylene perfluoroalkoxy polymer polypropene poly(tetrafluoroethene) solid-phase extraction solid-phase microextraction tributyltin chloride total phosphorus triphenyltin chloride volatile organic compounds

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107. Munch, J.W. 1995. EPA, Method 531.1—Measurement of N-methylcarbamoyloximes and N-methylcarbamates in water by direct aqueous injection HPLC with post column derivatization, Revision 3.1. Washington, DC. 108. Fatta, D., S. Canna-Michaelidou, C. Michael, E. Demetriou Georgiou, M. Christodoulidou, A. Achilleos and M. Vasquez. 2007. Organochlorine and organophosphoric insecticides, herbicides and heavy metals residue in industrial wastewaters in Cyprus. J. Hazard. Mater. 145: 169–179. 109. U.S. Environmental Protection Agency. 1992. Environmental Monitoring Systems Laboratory. Methods for the determination of organic compounds in drinking water, Supplement II, 500 Series. EPA-600/R-92/129. Washington, DC. 110. U.S. Environmental Protection Agency. 1983. Environmental Monitoring and Support Laboratory. Methods for chemical analysis of water and wastes. EPA-600/4-79-020 (method 420.2). Washington, DC. 111. American Society for Testing and Materials. 1980. ASTM Annual Book of Standards. Part 31. D3370. Standard Practice for Sampling Water. Philadelphia. 112. U.S. Environmental Protection Agency. 1988. Environmental Monitoring Systems Laboratory. Methods for the determination of organic compounds in drinking water, 500 Series. EPA-600/4-88/039. Washington, DC. 113. U.S. Environmental Protection Agency. 1996. Methods for organic chemical analysis of municipal and industrial wastewater. Method 610—Polynuclear aromatic hydrocarbons. Washington, DC. Available at http://www.accustandard.com/asi/pdfs/epa_methods/610.pdf (accessed July 28, 2008). 114. Sicilia, D., S. Rubio, D. Perez-Bendito, N. Maniasso, and E.A.G. Zagatto. 1999. Anionic surfactants in acid media: A new cloud point extraction approach for the determination of polycyclic aromatic hydrocarbons in environmental samples. Anal. Chim. Acta 392: 29–38. 115. Law, R.J. and J.L. Biscaya. 1994. Polycyclic aromatic hydrocarbons (PAH)—problems and progress in sampling, analysis and interpretation. Mar. Pollut. Bull. 29: 235–241. 116. Rawa-Adkonis, M., L. Wolska, and J. Namiesnik. 2006. Analytical procedures for PAH and PCB determination in water samples—error sources. Crit. Rev. Anal. Chem. 36: 63–73. 117. Green, D.R. and D. Le Pape. 1987. Stability of hydrocarbon samples on solid-phase extraction columns. Anal. Chem. 59: 699–703. 118. U.S. Environmental Protection Agency. 2008. Test methods for evaluating solid waste. Physical/chemical methods. EPA SW-846 5030/8240. Available at http://www.epa.gov/epaoswer/hazwaste/test/main.htm (accessed July 28, 2008). 119. Maskarinec, M.P., L.H. Johnson, S.K. Holladay, R.L. Moody, C.K. Bayne, and R.A. Jenkins. 1990. Stability of volatile organic compounds in environmental water samples during transport and storage. Environ. Sci. Technol. 24: 1665–1670. 120. American Public Health Association, American Water Works Association, Water Pollution Control Federation. 1989. Standard Methods for the Examination of Water and Wastewater, 17th edition. Washington, DC: APHA. 121. U.S. Environmental Protection Agency. 1994. Methods for organic chemical analysis of municipal and industrial wastewater. Method 1613—Tetra- through octa-chlorinated dioxins and furans by isotope dilution HRGC/HRMS. Washington, DC. Available at http://www.accustandard.com/asi/pdfs/ epa_methods/1613.pdf (accessed July 28, 2008). 122. Szymanski, A., Z. Swit, and Z. Lukaszewski. 1995. Studies of preservation of water samples for the determination of non-ionic surfactants. Anal. Chim. Acta 311: 31–36. 123. Karlsson, S., H. Wolrath, and J. Dahlen. 1999. Influence of filtration, preservation and storing on the analysis of low molecular weight organic acids in natural waters. Water Res. 33: 2569–2578. 124. Berdie, L., J.O. Grimalt, and E.T. Gjessing. 1995. Combined fatty acids and amino acids in the dissolved + colloidal fractions of the waters from a dystrophic lake. Org. Geochem. 23: 343–353. 125. Campos, M.L.A.M., R.F.P. Nogueira, P.R. Dametto, J.G. Francisco, and C.H. Coelho. 2007. Dissolved organic carbon in rainwater: Glassware decontamination and sample preservation and volatile organic carbon. Atmos. Environ. 41: 8924–8931. 126. Lara, L.B.L.S., P. Artaxo, L.A. Martinelli, R.L. Victoria, P.B. Camargo, and A. Krusche. 2001. Chemical composition of rainwater and anthropogenic influences in the Piracicaba River Basin, Southeast Brazil. Atmos. Environ. 35: 4937–4945. 127. WHO. 1998. Polynuclear Aromatic Hydrocarbons in Guidelines for Drinking-water Quality, Vol. 2, 2nd edition. Addendum to Health Criteria and Other Supporting Information, Geneva. Available at http:// www.emro.who.int/ceha/pdf/Guidelines_DrinkingWater_Edition2_Volume2_Addendum.pdf (accessed July 28, 2008).

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128. Chen, B., X. Xuan, L. Zhu, J. Wang, Y. Gao, K. Yang, X. Shen, and B. Lou. 2004. Distributions of polycyclic aromatic hydrocarbons in surface waters, sediments and soils of Hangzhou City, China. Water Res. 38: 3558–3568. 129. Kummerer, K., A. Eitel, U. Braun, P. Hubner, F. Daschner, G. Mascart, M. Milandri, F. Reinthaler, and J. Verhoef. 1997. Analysis of benzalkonium chloride in the effluent from European hospitals by solidphase extraction and high-performance liquid chromatography with post-column ion-pairing and fluorescence detection. J. Chromatogr. A 774: 281–286. 130. Wolska, L., M. Rawa-Adkonis, and J. Namiesnik. 2005. Determining PAHs and PCBs in aqueous samples: Finding and evaluating sources of error. Anal. Bioanal. Chem. 382: 1389–1397. 131. Lopez Garcia, A., E. Blanco Gonzalez, J.I. Garcia Alonso, and A. Sanz-Medel. 1992. Potential of micellemediated procedures in the sample preparation steps for the determination of polynuclear aromatic hydrocarbons in waters. Anal. Chim. Acta 264: 241–248. 132. Nikolaou, A.D., S.K. Golfinopoulos, M.N. Kostopoulou, and T.D. Lekkas. 2000. Decomposition of dihaloacetonitriles in water solutions and fortified drinking water samples. Chemosphere 41: 1149–1154. 133. Szymanski, A. and Z. Lukaszewski. 2000. Initial separation and preservation for long-term storage of non-ionic surfactants from raw and treated sewage. Water Res. 34: 3635–3639. 134. Luque, N., S. Rubio, and D. Perez-Bendito. 2007. Use of coacervates for the on-site extraction/preservation of polycyclic aromatic hydrocarbons and benzalkonium surfactants. Anal. Chim. Acta 584: 181–188. 135. Pichon, V. 2000. Solid-phase extraction for multiresidue analysis of organic contaminants in water. J. Chromatogr. A 885: 195–215. 136. Primus, T.M., D.J. Kohler, M. Avery, P. Bolich, M.O. Way, and J.J. Johnston. 2001. Novel field sampling procedure for the determination of methiocarb residues in surface waters from rice fields. J. Argic. Food Chem. 49: 5706–5709. 137. Penuela, G.A. and D. Barcelo. 1998. Application of C18 disks followed by gas chromatography techniques to degradation kinetics, stability and monitoring of endosulfan in water. J. Chromatogr. A 795: 93–104. 138. Penuela, G.A. and D. Barcelo. 1998. Photodegradation and stability of chlorothalonil in water studied by solid-phase disk extraction, followed by gas chromatographic techniques. J. Chromatogr. A 823: 81–90. 139. Aguilar, C., I. Ferrer, F. Borrull, R.M. Marce, and D. Barcelo. 1999. Monitoring of pesticides in river water based on samples previously stored in polymeric cartridges followed by on-line solid-phase extraction-liquid chromatography–diode array detection and confirmation by atmospheric pressure chemical ionization mass spectrometry. Anal. Chim. Acta 386: 237–248. 140. Berkane, K., G.E. Caissie, and V.N. Mallet. 1977. The use of Amberlite XAD-2 resin for the quantitative recovery of fenitrothion from water—a preservation technique. J. Chromatogr. A 139: 386–390. 141. Puig, D. and D. Barcelo. 1996. Determination of phenolic compounds in water and waste water, Trends Anal. Chem. 15: 362–375. 142. McNaught, A.D. and A. Wilkinson. 1997. IUPAC Compendium of Chemical Terminology. Oxford: Blackwell Scientific Publications.

3

Application of Passive Sampling Techniques for Monitoring the Aquatic Environment Graham A. Mills, Richard Greenwood, Ian J. Allan, Ewa Łopuchin, Janine Brümmer, Jesper Knutsson, and Branislav Vrana

CONTENTS 3.1 3.2

Introduction ........................................................................................................................ Concept of Passive Sampling .............................................................................................. 3.2.1 Equilibrium Sampling ............................................................................................ 3.2.2 Kinetic Sampling .................................................................................................... 3.2.3 Sampler Construction ............................................................................................. 3.2.3.1 Sorption Phase ......................................................................................... 3.2.3.2 Diffusion Barrier ...................................................................................... 3.2.4 Modeling and Calibration of Passive Sampling Devices ........................................ 3.2.5 Factors Affecting Passive Sampling ....................................................................... 3.2.6 Biofouling ............................................................................................................... 3.3 Recent Applications ............................................................................................................ 3.3.1 Hydrophobic Organic Compounds ......................................................................... 3.3.2 Polar Organic Compounds ...................................................................................... 3.3.3 Volatile Organic Compounds ................................................................................. 3.3.4 Organometallic Compounds ................................................................................... 3.3.5 Metals ..................................................................................................................... 3.3.6 Algal Toxins ............................................................................................................ 3.3.7 Applications in Ecotoxicity Assessment ................................................................. 3.3.8 Applications in Biomonitoring ............................................................................... 3.4 Quality Assurance, Quality Control and Validation .......................................................... 3.5 Use of Passive Sampling in Regulatory Monitoring .......................................................... 3.6 Future Trends ...................................................................................................................... Acknowledgments ........................................................................................................................ References ....................................................................................................................................

3.1

41 42 43 44 45 45 45 46 47 48 50 50 50 54 54 55 55 56 57 57 59 60 61 61

INTRODUCTION

A challenge for the environmental chemist is the development of reliable sampling and analytical procedures for the representative assessment of water quality.1-4 Currently, most water monitoring methods rely on the collection at defined periods of discrete spot, grab, or bottle samples followed 41

42

Analytical Measurements in Aquatic Environments

by instrumental analysis in the laboratory. As many pollutants can be present in the water phase at very low concentrations, the collection of large volumes of water is often needed for analysis. In addition, the analysis of spot water samples provides only a snapshot of the levels of pollutants at the time of sampling. This may not give an accurate assessment of water quality in situations where pollutant concentrations fluctuate widely and where episodic pollution events occur. Data from round robin exercises of the analysis of pollutants found in spot water samples showed that there are often recurring problems of interlaboratory reproducibility especially when the pollutants are present in trace concentrations.5 Issues of poor reproducibility are often linked to the procedures used in collecting the water for analysis. There are several options available to improve the sampling procedures and hence the quality of the water monitoring data obtained. One possibility is to significantly increase the frequency of sampling or to install automatic sampling systems that can collect numerous water samples over a given time period. The latter systems are often installed at sites of strategic importance (e.g., monitoring stations near transnational boundaries and locations for drinking water capitation), but they cannot be used in widespread monitoring networks. The cost of the equipment is high and a secure site is needed in which to locate the apparatus. Biomonitoring can be used as an alternative to spot sampling. A number of test species (e.g., mussels and fish) can be employed depending on the water body being investigated. These sentinel organisms are deployed for extended periods of time during which they accumulate pollutants from the surrounding water. Analysis of tissue extracts can give an indication of the level of waterborne contamination. A number of factors can increase the uncertainty of the results obtained using these procedures including metabolism, depuration rates, excretion, stress, viability, and the condition of test organisms. Furthermore, the extraction procedures required for the analysis of tissue samples are complex and time-consuming. Another option is the use of passive sampling. These devices have been used since the early 1970s, when they were first used for the measurement of gaseous pollutants in air;6 recently, they have shown much promise as useful tools for the measurement of a wide range of priority pollutants in water. Passive samplers avoid many of the above problems since they sample compounds in situ without affecting the concentration in bulk solution. The mass of analyte accumulated by a sampler reflects either the aqueous concentration with which the device is at equilibrium or the time-weighted average (TWA) concentration with which the sampler was exposed during deployment. Such devices can be exposed in the field for time periods up to several months. The technology is relatively inexpensive, simple to use and, as the devices have no mechanical parts, they do not require any external source of energy for their operation. They have been used in complex monitoring networks and can be deployed in remote areas without any infrastructure. The devices continuously sequester pollutants from the bulk water matrix and trap them in a suitable sorbent medium. A number of different devices are available commercially or as laboratory prototypes. Several reviews have been published describing the design, calibration procedures, figures of merit, and applications of the different samplers for monitoring the aquatic environment.7-11 In addition, a book describing the semipermeable membrane device (SPMD)12 and a general text on all passive sampling techniques for environmental monitoring13 is available. Due to the extensive number of scientific publications in the field, this chapter is not meant to be exhaustive and concentrates only on developments and potential applications of the technology from the last 10 years.

3.2 CONCEPT OF PASSIVE SAMPLING Passive sampling can be defined as any sampling technique based on the movement (by diffusion) of analyte molecules from the sampled medium to a receiving phase contained in a sampling device. This mass transfer process is driven by a difference in chemical potentials of the analyte in the two media. This process continues until equilibrium is reached in the system, or until the sampling process is stopped.14 Analytes are retained in a suitable medium within the device, known as a receiving or sorption phase. This can be a solvent, chemical reagent, absorbent, or

43

Application of Passive Sampling Techniques

Bulk water

Aqueous diffusional layer

Biofilm

Concentration

Diffusional path

Membrane Sorption phase

FIGURE 3.1 Concentration profiles in a passive sampling device. The driving force of accumulation is the difference in chemical potentials of the analyte between the bulk water and the sorption phase. The mass transfer of an analyte is governed by the overall resistance along the whole diffusional path, including contributions from the individual barriers (e.g., aqueous boundary layer, biofilm layer, and membrane).

porous adsorbent material. Unlike dynamic extraction methods (e.g., liquid–liquid extraction or solid-phase extraction), the aim is not to exhaustively extract the dissolved analyte molecules from the water phase. The sorption of a pollutant molecule from the bulk water phase follows the pathway shown in Figure 3.1. The uptake of an analyte by a passive sampling device is a multistage mass transfer process. First, water containing analyte molecules enter the space that protects the sampler from mechanical damage (usually a cage or well or cavity in the sampler housing). Here, transport is by convective processes. Molecules then diffuse through the aqueous boundary layer and biofilm layer (if present). Finally, analytes diffuse through the membrane and accumulate in the sorption phase, which has a high affinity for the compounds of interest. This general scheme can vary according to the specific construction of the sampling device. The exchange kinetics between a passive sampler and the water phase can be described by a firstorder, one-compartment mathematical model: k CS(t) = CW __1 (1 - e-k2t) k2

(3.1)

where CS(t) is the concentration of the analyte in the sampler at exposure time t, CW is the concentration of the analyte in the bulk water phase, and k1 and k2 are the uptake and offload rate constants, respectively. Two accumulation modes, either equilibrium or kinetic sampling, can be distinguished in the operation of a sampler (Figure 3.2).

3.2.1

EQUILIBRIUM SAMPLING

In equilibrium sampling, the exposure time is sufficiently long to permit the establishment of thermodynamic equilibrium between the water and sorption phases. In this case the dissolved analyte concentration can be estimated using the sorption phase–water partition coefficient (KSW): CS KSW = ___ CW

(3.2)

The theory of equilibrium passive sampling devices has been published by Mayer et al.15 The basic requirements of the equilibrium sampling approach are that equilibrium concentrations are

44

Analytical Measurements in Aquatic Environments Equilibrium regime

Concentration in the sampler

Kinetic regime

t50

Time

FIGURE 3.2 Passive sampling devices operate in two main regimes: kinetic and equilibrium.

reached after a known response time, and the device response time needs to be shorter than any fluctuations in concentration in the environmental medium. Analyte depletion from the sampled medium must not occur during the sampling process, as otherwise this would disturb the equilibrium of the system. The amount of analyte accumulated by a passive sampling device is independent of the sample volume. The analyte concentration measured by equilibrium samplers does not necessarily reflect all of the contamination events during the whole sampling period but provides a snapshot of the concentration representative for the equilibration period. The sorption phase–water partition coefficient (KSW) is the driving force for the uptake of compounds by passive sampling devices. Measurement of KSW in the laboratory can be difficult, particularly for hydrophobic compounds, as results can be biased through errors in the measurement of their concentration in the water phase. To overcome this problem, a cosolvent approach has been developed. Here, compounds are equilibrated with samplers using a range of water/ cosolvent mixtures (e.g., water/methanol) and the partition coefficients measured. The cosolvent increases the solubility of the analytes in the aqueous phase and also reduces the sorption to any solid phases present. Extrapolation of the curve of log partition coefficient versus percentage cosolvent to zero percent cosolvent yields the true partition coefficient of the compound between the sorption phase and the water. Smedes16 and Yates et al.17 successfully used this approach to determine the partition coefficients of a range of hydrophobic organic contaminants between silicone rubber materials and water. In some cases, the partition coefficient can be estimated using linear relationships between KSW and the corresponding n-octanol–water partition coefficients.12,17

3.2.2

KINETIC SAMPLING

With kinetic or TWA sampling, it is assumed that the rate of mass transfer to the sorption phase is linearly proportional to the difference between the chemical activity of the contaminant in the water phase and that in the sorption phase. During the initial phase of sampler exposure, the rate of desorption of analyte from the sorption phase to water is negligible and the sampler works in the linear uptake mode. The amount of analyte accumulated is therefore linearly proportional to its TWA concentration in water, even for situations where aqueous concentrations fluctuate over time (Figure 3.2). In this case Equation 3.1 reduces to CS(t) = CW k1t

(3.3)

Application of Passive Sampling Techniques

45

Equation 3.3 can be rearranged to mS(t) = CW RSt

(3.4)

where mS(t) is the mass of analyte accumulated in the sorption phase after an exposure time t and RS is the sampling rate. RS may be interpreted as the volume of water cleared of analyte per unit of exposure time (e.g., mL h-1 or L day-1) by the device. If RS is known, CW (the TWA concentration of a pollutant in the water phase) may be estimated from the exposure time (t) and the amount (mS) of the analyte collected by the sorption phase. For devices operating in the TWA mode, RS does not vary with aqueous concentration but is often affected by water flow (turbulence), water temperature, and the extent of biofouling of the diffusive surface. TWA sampling can be used in situations where analyte concentrations are variable and can be used to measure episodic pollution events. As integrative samplers permit the measurement of concentrations over extended time periods, they can provide a more realistic picture of contaminant levels than can be achieved by the collection of discrete spot samples of water.

3.2.3

SAMPLER CONSTRUCTION

The selection of materials used for the construction of passive samplers is based on a number of criteria, including price, mechanical strength, the maximum sampling rate, and accumulation capacity. 3.2.3.1 Sorption Phase Analytes may accumulate in the sorption phase either by adsorption onto the surface of solid sorbent materials or by absorption in absorbent liquids or polymers that behave like subcooled liquids.The advantage of solid adsorbents is the potential to select materials with a high affinity and selectivity for target analytes. However, the sorption capacity of adsorbents is usually limited, and the description of adsorption/desorption kinetics of analytes to adsorbents is complex. Typically, the adsorbent materials used in passive samplers are similar to those used in solid-phase extraction techniques. Absorbents usually have a higher sampling capacity but a lower selectivity than adsorbents. Many materials with a noncrystalline polymeric structure have been employed as absorbents in sampling devices. This type of sampling device consists only of a sorption phase that is not separated from the bulk water matrix by an extra diffusion-limiting membrane. The sampling rate of analytes is determined by diffusion into the sorption phase polymeric material itself or by diffusion into the aqueous boundary layer at the sampler surface. Recently, Rusina et al.18 evaluated the performance properties (e.g., release of oligomers, swelling effects in solvents, analyte diffusion coefficients, and partition coefficients) of a range of polymers used in single-phase samplers for the measurement of hydrophobic compounds. She proposed that silicone rubber is an attractive sorption phase owing to its high partition coefficient and low mass transfer resistance for hydrophobic analytes such as polynuclear aromatic hydrocarbons (PAHs). 3.2.3.2 Diffusion Barrier An important performance characteristic of passive samplers that operate in the TWA regime is the diffusion barrier that is inserted between the sampled medium and the sorption phase. This barrier is intended to control the rate of mass transfer of analyte molecules to the sorption phase. It is also used to define the selectivity of the sampler and prevent certain classes (e.g., polar or nonpolar compounds) of analytes, molecular sizes, or species from being sequestered. The resistance to mass transfer in a passive sampler is, however, seldom caused by a single barrier (e.g., a polymeric membrane), but equals the sum of the resistances posed by the individual media (e.g., aqueous boundary layer, biofilm, and membrane) through which analyte diffuses from the bulk water phase to the sorption phase.19 The individual resistances are equal to the reciprocal value of their respective mass transfer coefficients and are additive. They are directly proportional to the thickness of the barrier

46

Analytical Measurements in Aquatic Environments

and are inversely proportional to the permeability (a product of diffusion coefficient and solubility in the medium) of the medium for a given analyte.19 The dominant barrier to mass transfer for a particular compound is the one that contributes more than 50% to the total resistance. High sampling rates are obtained when the transport resistance of the membrane is much smaller than that of the aqueous boundary layer. Consequently, the product of membrane diffusion coefficient and membrane/water partition coefficient (D M KMW) is called the membrane permeability, and this can be used for ranking materials for use in the construction of passive sampling devices.18 Often, the dominant barrier to mass transfer is used to classify samplers into two categories, either diffusion-based or permeation-based devices.14,20 In diffusion-based samplers, analyte molecules reach the sorption phase by diffusion through a static boundary layer of water contained as a well-defined gap between the bulk water phase and the sorption phase. In permeation-based samplers, compounds must also diffuse through a porous or nonporous membrane. However, this classification can be artificial, as many sampling devices, although designed as “permeation samplers,” have later been shown to accumulate some analytes under water boundary layer control, and thus work as diffusion samplers. The SPMD and the Chemcatcher® device used for sampling hydrophobic compounds are examples of such behavior.21,22 Passive samplers are usually designed to maximize the amount of analyte sampled in order to detect low levels of pollutants present in water. Diffusion samplers mostly use a “tube” design, where the receiving phase is located inside a long, narrow inert tube or a capillary. The space between the edge of the sampler and the surface of the sorption phase is filled with a stagnant layer of the sampled water. Diffusion through this immobilized layer of water defines the sampling rate. To avoid fluctuations in the sampling rate, caused by disturbance of the diffusion distance by movement in the bulk water phase, such diffusion samplers are characterized by a low ratio of sampler surface area to diffusion distance. An example is the solid-phase microextraction (SPME) sampling device in which the fiber is retracted a known distance into its needle housing during operation.23-25 Since mass transfer is directly proportional to surface area, tube-type samplers (characterized in most cases by a small surface area) are less sensitive than badge-type samplers with a large surface area. In water monitoring badge-type samplers predominate. In cases where the aqueous boundary layer controls uptake, sampling kinetics in flat samplers with a large surface area are more affected by fluctuations in water velocity. To minimize the impact of such fluctuations on mass transfer, a permeable polymeric membrane (e.g., used in SPMD,21 membrane enclosed sorptive coating (MESCO),26 and Chemcatcher27 samplers) or a gel layer used in the diffusive gradient in thin films (DGT28 sampler) are used to separate the sorption phase from the bulk water environment. However, the use of such membranes (or any other additional diffusion barriers) that reduce flow sensitivity also automatically reduce the maximum sampling rate and thereby result in decreased sensitivity.19 Several types of polymeric membrane have been used for the construction of passive samplers. Nonporous membranes include low-density polyethylene (LDPE),21,22,29 polypropylene, polyvinylchloride,27,30 polydimethylsiloxane (PDMS),16,30-32 polyacrylate,33 and other nonpolar polymers.34 Microporous membranes include glass fiber,27 regenerated cellulose26,27,35 nylon, polysulfone,27 polyethersulfone,36 and polyacrylamide hydrogel.28 The membrane acts in effect as a barrier; the dissolved analytes can pass through whereas particulates, microorganisms, and macromolecules with a size greater than the exclusion limit cannot. Without the protection of the membrane, there is an increased risk of deterioration of the sorption phase due to biofouling.

3.2.4

MODELING AND CALIBRATION OF PASSIVE SAMPLING DEVICES

A number of models has been developed to improve the understanding of the kinetics of analyte transfer to passive samplers.9,12,19,37 These models are essential for understanding how the amount of analyte accumulated in a device relates to its concentration in the sampled aquatic environment as well as for the design and evaluation of laboratory calibration experiments. Models differ in the number of phases and simplifying assumptions that are taken into account, for example, the

Application of Passive Sampling Techniques

47

existence of (pseudo-) steady-state conditions, the presence or absence of linear concentration gradients within the phases, the way in which transport within the boundary layers is described, and whether or not the aqueous concentration is constant during the sampler exposure. The substance-specific kinetic constants, k1 and k2, and partition coefficient KSW (see Equations 3.1 and 3.2) can be determined in two ways. In theory, kinetic parameters characterizing the uptake of analytes can be estimated using semiempirical correlations employing mass transfer coefficients, physicochemical properties (mainly diffusivities and permeabilities in various media), and hydrodynamic parameters.38,39 However, because of the complexity of the flow of water around passive sampling devices (usually nonstreamlined objects) during field exposures, it is difficult to estimate uptake parameters from first principles. In most cases, laboratory experiments are needed for the calibration of both equilibrium and kinetic samplers. Calibration of equilibrium samplers depends on estimating KSW. Tank exposure studies are used and the concentration of the analyte of interest in the two phases at equilibrium is measured. For highly nonpolar compounds bias can be introduced into the estimation of the partition coefficients since these compounds can bind to the walls of the calibration tank, to dissolved organic carbon (DOC), and to any suspended organic matter. This can lead to an overestimation of the freely dissolved fraction in the water phase. To overcome this problem, a cosolvent method using a range of concentrations of methanol in the external water phase has been used.16 For kinetic samplers, the key parameter to be determined is the apparent water sampling rate (RS) that has units of volume per unit time. This is directly related to the effective sampling area of the sampler and is affected by environmental variables such as temperature and turbulence at the face of the sampler. A number of methods have been used to estimate this parameter including static exposure, static exposure with renewal, and continuous flow; these have recently been reviewed by Stephens and Müller.40 Ideally, these should provide estimates that cover the range of water temperatures and turbulence conditions (usually achieved by varying the stirring rate in the calibration tank), which would be found in typical field exposures. The problems of bias for very hydrophobic compounds are similar to those described for the equilibrium samplers, where the presence of dissolved or suspended organic carbon can reduce the effective (freely dissolved) concentration of analytes in the calibration tank.40

3.2.5

FACTORS AFFECTING PASSIVE SAMPLING

A number of methods has been developed to compensate for the effect of environmental variables on sampler performance. Booij et al.41 and Huckins et al.42 described a method to estimate the uptake kinetics in both laboratory and field situations by spiking sampling devices prior to exposure with a number of performance reference compounds (PRCs) that do not occur in the environment (usually deuterated analogs of the compounds being measured). Where factors influencing uptake kinetics affect the offloading kinetics of PRCs in an identical manner, the release rate of these compounds is a measure of the exchange kinetics between the sampler and water, and can be used to compensate for variations in environmental conditions during field exposures.43 The PRC approach is applicable in situations only where the exchange kinetics are isotropic. This is the case when the overall uptake of target pollutants and release of PRCs are governed by first-order kinetics and the sum of the resistances to mass transfer across the sampler is equal in both directions. These characteristics are observed in samplers where the sorption phase consists of an immiscible liquid or a nonpolar polymeric film (a subcooled liquid).42,44 The PRC approach may not be applicable, however, for samplers fitted with solid-phase sorbent receiving phases (e.g., the Polar Organic Chemical Integrative Sampler (POCIS) or the polar pollutant variant of the Chemcatcher sampler) because of the fundamental differences between solute partitioning and adsorption phenomena.45 Also, as the solidphase sorbents often act as an infinite sink with a very high sorption capacity, the selection of a PRC with a sufficient fugacity to enable it to be released from such samplers is problematic. Similar problems exist with devices for measuring metals as chelating agents are often used as receiving phases, and the element, once sequestered, can only be released by the addition of a strong acid.

48

Analytical Measurements in Aquatic Environments

FIGURE 3.3 Examples of passive samplers affected by deposition of suspended particulate matter and biofouling: (a) silicone strip sampler, (b) nonpolar version of the Chemcatcher, (c) MESCO sampler fitted with a cellulose membrane, and (d) MESCO sampler fitted with polyethylene membrane (front) and SPMD (back).

3.2.6

BIOFOULING

Unprotected surfaces submersed in water eventually become colonized by bacteria and various flora and fauna that may ultimately form a biofilm (Figure 3.3). The thickness and density of this biofilm vary not only from exposure to exposure but also from zone to zone on the same surface. The composition of biofilms depends on the properties of the aquatic system being measured as well as the properties of the material colonized by microorganisms. During passive sampling, buildup of a biofilm layer can increase the resistance to mass transfer of sampled analytes, thus reducing their sampling uptake rates. Moreover, if the microbial communities that develop on the surface of the sampler possess a potential for biodegradation, they can decompose the analytes in the water that is in contact with the biofilm. This would result in an increase in the concentration gradient between the sorption phase and the biofilm layer. As a result, compounds with low KSW values may be released from the sorption phase back to the biofouling layer and subsequently degraded there. Such effects may result in a serious underestimation of analyte concentrations. Colonizing organisms may also physically damage the surface of membranes that are made of a biodegradable material (e.g., cellulose). Paschke et al.46 observed up to three times faster analyte exchange kinetics with the MESCO sampler in the field in comparison with a laboratory calibration study. Besides the effects of water turbulence, the increased exchange kinetics could be explained by degradation of the cellulose diffusion-limiting membranes during the field exposure, resulting in a significant loss of resistance to analyte exchange between the sampler and water. The effect of biofouling on sampling kinetics is shown in Figure 3.4. LDPE membranes were prefouled for one month in water collected from a park fountain. Membranes became heavily fouled with a thick algal and bacterial film. The fouled membranes were used for the construction of Chemcatcher samplers fitted with sorption phases previously spiked with several PRCs. Samplers fitted with either fouled or unfouled membranes were simultaneously exposed (rotation speed: 40 rpm and water temperature: 11°C) in a laboratory flow through a calibration system

49

Application of Passive Sampling Techniques 1.1 1.0

MD(t)/MD(0)

0.9 0.8 0.7 0.6 0.5 0.4

D10-Acenaphthene; no biofouling D10-Acenaphthene; simulated biofouling

0.3 0

100 Time (h)

200

300

200

300

1.1 1.0

MD(t)/MD(0)

0.9 0.8 0.7 0.6 0.5

D10-Fluorene; no biofouling D10-Fluorene; simulated biofouling

0.4 0

100 Time (h)

FIGURE 3.4 Biofouling reduces the exchange kinetics of PRCs (deuterated acenaphthene and fluorene) between the nonpolar Chemcatcher sampler (fitted with either fouled or unfouled LDPE membranes) and water. The experiment was performed in a laboratory flow-through calibration system at a water temperature of 11°C with simulated water turbulence of 40 rpm. MD(t)/MD(0) is the fraction of the PRC remaining in the sampler during exposure.

as described by Vrana et al.43 Offload kinetics of PRCs from fouled samplers were compared with those from unfouled samplers. The heavy degree of biofouling caused a reduction of up to 50% in the elimination rate of PRCs: although a significant effect, it is less dramatic than might be expected. Huckins et al.29 reported a 20–70% impedance in the uptake of PAHs in cases of severe biofouling on the surface of SPMDs. Their model describing the mass transfer in a biofilm indicated that it behaved like an immobilized water layer with a resistance that is independent of the biofilm/water partition coefficient. This would result in a similar mobility of compounds in the biofilm since this is independent of their hydrophobicity.19 Similarly, Richardson et al.47 observed that biofouling caused a reduction of up to 50% in the uptake of PAHs and organochlorine pesticides by SPMDs. It has been suggested by several authors that PRCs can be used to correct biofouling during deployment,42,47 but more experimental evidence is needed. To minimize the effects of excessive fouling, prolonged exposures of samplers should be avoided.48 Biofouling may be reduced by the selection of suitable construction materials. For example, the polyethersulfone diffusion membranes used in POCIS and the polar version of the Chemcatcher are less prone to fouling than the LDPE membranes used in SPMDs. This may be due to the low surface energy properties of polyethersulfone, discouraging the initial onset of the biofouling process by

50

Analytical Measurements in Aquatic Environments

creating unfavorable conditions for the settlement of colonizing microorganisms.49 Alternatively, coating the membrane with a low surface energy material, for example, Nafion®, can be used to inhibit fouling.50 Some solvent-filled membrane devices are protected from fouling by the slow diffusion of the solvent (e.g., n-hexane) from the sampler during field exposure. Such chemicals inhibit the growth of microorganisms. Protective screens made of copper or bronze mesh have also been shown to inhibit biofouling; however, they cannot be used when monitoring heavy metals. Recently, a novel approach using antibiotics added to the DGT device has been attempted in order to prevent the development of biofilms.51 Attempts to inhibit fouling by applying antifouling agents to SPMDs prior to field deployments have proved unsuccessful.52

3.3

RECENT APPLICATIONS

Passive samplers can combine sampling, selective analyte isolation, preconcentration, and in some cases preservation of speciation in a single step. They eliminate the need for an external energy supply at the sampling site and allow the entire sampling process to be simplified. Following exposure, samplers are transported to the laboratory for further processing. These steps are often similar to those used in conventional sample extraction, sample preconcentration, and instrumental chemical analysis. Passive sampling technology is widely applicable. It can be used in monitoring studies aimed at screening for the presence or absence of pollutants, investigating temporal and spatial trends in levels of pollutants, speciation of contaminants, assessment of pollutant fate, measurement of TWA concentrations, and in biomimetic sampling (an approach to simulate contaminant uptake in biota). Several recently published reviews and monographs are available that describe the design, construction, and use of passive samplers. The reader should refer to these for a fuller description of the devices and their use for monitoring pollutants in the aquatic environment.7-11,13,30,53 Table 3.1 summarizes the different devices that have been used to measure organic and inorganic contaminants in water.

3.3.1

HYDROPHOBIC ORGANIC COMPOUNDS

Hydrophobic organic pollutants include several groups of compounds, such as organochlorine pesticides, polychlorinated biphenyls (PCBs), polychlorinated dibenzo-p-dioxins, polychlorinated dibenzofurans, and PAHs. The concentrations of nonpolar pollutants dissolved in water are frequently very low, usually less than 1 ppb. This is due to their low aqueous solubilities. These compounds adsorb strongly onto particulate matter and are deposited in the sediment. Nevertheless, because of their persistence and potential for bioaccumulation, it is necessary to monitor the concentrations of these chemicals in water. A range of passive sampling devices has been developed and applied for monitoring hydrophobic organic pollutants in water.14,22,34,53,78 Among these, the SPMD is the most mature technique for measuring hydrophobic organic contaminants.21 The design of the SPMD was first published in 1990, since when over 200 studies have been reported.79 Several reviews and one monograph on this technology are available.11,30,80,81

3.3.2

POLAR ORGANIC COMPOUNDS

Environmental research interests have recently extended from persistent hydrophobic organic chemicals to more hydrophilic organic compounds. The latter include some polar pesticides, many pharmaceuticals and personal care products, microbial toxins, and endocrine disrupting compounds.4 Polar organic compounds are often present at low concentrations in the aquatic environment, which poses a problem for most conventional sampling and analytical procedures. Recently, considerable effort has been directed toward the development of extraction methods suitable for the preconcentration of polar organic compounds commonly found in water bodies. Many of these methods use

Paper strips impregnated with binding agents Hydrophobic adsorbent

Gore-Sorber

Microporous membrane of polytetrafluoroethylene— GORE-TEX®

Polyethylene membrane (organics), porous membrane (metals)

Gaiasafe sampler

Ecoscope

Stagnant layer of water

Granular activated carbon Hexane (organics) chelating resin (metals)

Dosimeter

Microporous ceramic material Nonporous LDPE membrane or porous polyethersulfone membrane Cellulose acetate membrane

Barrier to Diffusiona

Hydrogel layer

Chelating and C18 Empore™ sorbent disks

Various solid sorbent materials Various EmporeTM sorbent disks

Sorption Phase

Diffusion gradient in Binding resin thin films (DGT) impregnated in a hydrogel

Chemcatcher (metals version)

Chemcatcher (organics version)

Ceramic dosimeter

Sampler

Screening

Equilibrium

BTEX, MTBE, PAHs. VOCs, semi-VOCs

Qualitative screening

Integrative, speciation, screening, mimicking biological uptake Integrative

Integrative, speciation

Integrative sampling in groundwater Integrative

Sampling Purpose

Metals, anions, organic compounds

Hydrophobic organic compounds, heavy metals

BTEX and atrazine

Range of heavy metals included in priority pollutant lists, including organotin and mercury compounds Most heavy metal pollutants, phosphorus, sulfide, and radioactive metal isotopes

PAHs, BTEX, chlorinated hydrocarbons Nonpolar and polar organics

Analytes

TABLE 3.1 Overview of Different Passive Sampling Devices Used for Monitoring Pollutants in Water

14 days

2 days to 2 months

Up to 2 months 2–4 weeks

1 day to 4 weeks

2–4 weeks

14 days to 1 month

Up to 1 year

Typical Deployment Period

Thermal desorption

Direct injection of solvent or after concentration or extraction with acid Solvent extraction

Solvent extraction

Extraction with acid

Extraction with acid

Solvent extraction or thermal desorption Solvent extraction

Sample Preparation for Chemical Analysis

61

60

59

58

57

continued

55,56

26

54

Reference

Application of Passive Sampling Techniques 51

Nonporous LDPE membrane

Water or gas

A liquid reagent consisting of nitric acid and gold (Au3+) solution Aqueous solution

Polyethylene diffusion bags (PDB) Passive integrative mercury sampler (PIMS)

Flux-proportional sampler

Passive in situ continuous extraction sampler (PISCES) POCIS

Permeation liquid membrane (PLM)

Various granular adsorbent materials Various adsorbent materials

Hexane

Nonporous LDPE membrane

Various granular adsorbent materials

A porous cartridge permeable to water

Polyethersulfone membrane

An immiscible liquid membrane containing specific metal ion carrier Semipermeable membrane filter

Silicone-polycarbonate membrane

Regenerated cellulose or LDPE Water boundary layer

Passive sampler

Negligible depletion-SPME

MESCO

The sorption phase itself acts as a diffusion barrier

Barrier to Diffusiona

Nonporous polyethylene or silicone materials Silicone rods or bars coated with silicone Glass fibers coated with a thin layer of various sorbent materials

Sorption Phase

LDPE and silicone strips

Sampler

TABLE 3.1 (continued)

Integrative

Bioavailable metal species

Equilibrium sampling in groundwater Preconcentration, screening

Integrative

Equilibrium

Integrative

Integrative

Sampling Purpose

Herbicides and pharmaIntegrative ceuticals with log KOW < 3 Wide range of Flux-proportional contaminants sampling in soil and groundwater

PCBs

Heavy metals

PAHs, PCBs, organochlorine pesticides Hydrophobic chemicals, including PAHs, PCBs, petroleum hydrocarbons, organochlorine pesticides, aniline, phenols Chlorobenzenes, nitrobenzenes, and nitrotoluenes Polar organic compounds, VOCs, metals, trace elements Neutral mercury species

Hydrophobic organic compounds

Analytes

Up to 2 months 1 month

2 weeks

Hours

Weeks to months

2 weeks

Up to 1 day

Hours

2 weeks

1 month

Typical Deployment Period

Solvent extraction

Solvent extraction

Analysis of a subsample from the acceptor solution Volume reduction of the receiving phase

Conventional analysis of the receiving water phase Acid extraction

Solvent extraction

Thermal desorption in GC inlet

Thermal desorption

Solvent extraction

Sample Preparation for Chemical Analysis

70

35

69

68

67

66

65

64

25

62,63

Reference

52 Analytical Measurements in Aquatic Environments

Organic solvent

A water-insoluble organic complexing mixture diffuses to the exterior surface of the sampler through a polymeric membrane Aqueous solution

a

Organophosphates

Pesticides

BTEX, PAHs, organometallic compounds

Nonporous LDPE membrane

Water boundary layer

Divalent metal ions

Divalent metal ions

Hydrophobic organic compounds

Hydrophobic organic compounds Polar phytotoxins

Phenols, acid herbicides, triazines

Water boundary layer

An immiscible immobilized liquid membrane containing specific metal ion carriers

Membranes made of porous materials Nonporous LDPE membrane

Cellulose acetate membrane

PDMS membrane

Integrative

Integrative

Integrative field sampling, preconcentration of trace elements, mimicking biological membranes Screening

Preconcentration, in situ sampling, determination of labile metal ions in grab samples

Integrative

Integrative

Integrative

Integrative

In the aquatic environment, the barrier to diffusion will also include a water boundary layer and in some cases a biofilm layer.

Thin layer Various adsorbent chromatographic materials plate LDPE bags Trimethylpentane containing trimethylpentane solvent (TRIMPS) TWA-SPME Glass fibers coated with a thin layer of various sorbent materials

Supported liquid membrane (SLM)

Stabilized liquid membrane device (SLMD)

Solvent-filled Hexane dialysis membranes SPATT Adsorbent polymeric resin SPMD Triolein

Sampler according to Kot-Wasik

Up to several days

1 month

1 month

Days

Days to several weeks

1 month

1 week

1 month

1 month

Thermal desorption in GC inlet

Direct analysis of the receiving phase solvent

Solvent extraction

Dialysis in organic solvents, size exclusion chromatography Extraction with acid

Analysis of a subsample of solvent is taken and analyzed without further cleanup steps Volume reduction of the receiving phase Solvent extraction

22,38,77

76

75

74

73

29

72

71

Application of Passive Sampling Techniques 53

54

Analytical Measurements in Aquatic Environments

specially formulated solid-phase extraction media and some of these can also serve as receiving phases for passive samplers for measurement of this class of pollutants. The first sampler (POCIS) reported for this range of chemicals was developed at US Geological Survey. This sampler uses a triphasic sorbent mixture (Isolute ENV+ polystyrene divinylbenzene and Ambersorb 1500 carbon dispersed on S-X3 Biobeads) or the Oasis HLB sorbent as the receiving phase and a polyethersulfone diffusion-limiting membrane.36 It has been used to monitor polar pesticides, prescription and over-the-counter drugs, steroids, hormones, antibiotics, and personal care products.36 The POCIS samples hydrophilic chemicals from the dissolved water phase and permits the determination of TWA concentrations over extended periods (several weeks). To date, more than 100 hydrophilic organic contaminants have been identified in extracts obtained from the receiving phase of POCIS.45 Another sampler suitable for the monitoring of a broad range of polar organic contaminants is one variant of the Chemcatcher. It consists of an Empore™ disk receiving phase overlain with a polyethersulfone diffusion-limiting membrane.27,34 This device is suitable for monitoring chemicals with log KOW < 3, and its functionality can be modulated by choosing the appropriate receiving phase disk chemistry within the Empore disk range, for example, either modified polystyrenedivinylbenzene copolymers (SDB-XC or SDB-RPS) or ion-exchange (Cation-SR or Anion-SR) phases. Mills et al.82 recently reviewed the use of passive sampling devices for the measurement of pharmaceuticals and personal care products in different aquatic environments. A number of potentially valuable forensic applications of the technology were identified, such as estimating illicit drug usage from the population within a given wastewater catchment area. It was highlighted that more calibration data (in terms of uptake rates) for frequently detected pharmaceutical compounds and related products are needed for both the Chemcatcher and the POCIS.83–85

3.3.3

VOLATILE ORGANIC COMPOUNDS

Passive samplers are widely used in monitoring volatile organic chemicals (VOCs) in groundwater. Such samplers have the potential to reduce costs of monitoring from the high levels associated with the use of pumps to sample the test wells. Moreover, the risk of loss of volatile analytes during sample transport and storage is substantially reduced once the compounds are accumulated in the sampler sorption phase. Equilibrium-based passive samplers used in groundwater monitoring typically consist of a closed container composed of a semipermeable membrane containing a gas or water which is free of the target analytes. When these sampling devices are deployed in VOC-contaminated groundwater, the analytes diffuse inside the sampler until equilibrium is reached between VOC concentrations in the ambient water and the gas or water inside the device.86 The equilibrated device is collected and the sample can either be immediately sealed in the sampler or be transferred to a vial, depending on requirements. An equilibration time of 1–7 days is typical for this type of sampler.87–90 A database of diffusion-based equilibrium passive samplers and their applications in monitoring of VOCs is maintained at a website.91 Among the kinetic sampling devices, ceramic dosimeters have been used successfully for the long-term surveillance of VOCs.92 They use a ceramic tube as the diffusion-limiting barrier that encloses a receiving phase consisting of solid sorbent beads. Over a three-month deployment in a contaminated aquifer, the ceramic dosimeter provided TWA concentrations of benzene, toluene, ethylbenzenes, xylenes, and naphthalenes. The levels obtained matched closely those found in spot water samples that were taken frequently over the trial period.54

3.3.4

ORGANOMETALLIC COMPOUNDS

Passive sampling devices have been used to measure a number of organometallic species, including those of lead, mercury, and tin. Følsvik et al.93,94 and Harman et al.95 reported the use of SPMDs for

Application of Passive Sampling Techniques

55

monitoring tributyltins. A variant of the Chemcatcher sampler has been developed and calibrated for the measurement of TWA concentration of organotin compounds.96 Ouyang et al.23 demonstrated the feasibility of using SPME as an in situ passive sampler for the determination of TWA concentrations of a range of organic chemicals in water. The SPME technique has been used for measuring organometallic species of lead, mercury, and tin in spot samples of water.77 It may be possible to extend this technique for use as a passive sampler for organometallic compounds.

3.3.5

METALS

Besides the use of passive sampling for measurement of metal ions, there is also a significant interest in using these devices to characterize the speciation of metals in water, that is, differentiating between free, inorganic, and organic bound metal species and organometallic compounds (see Table 3.1). Among the passive sampling techniques for metals, the most widely used is the diffusive gradients in thin films (DGT) device.28,97 Other devices based on the permeation of analytes through a variety of membrane materials, such as the metals version of the Chemcatcher, are finding an increasing range of applications (Table 3.1).55 In passive samplers, metals are usually accumulated on a Chelex-based sorption phase. After deployment, analytes are extracted from the receiving phase of samplers using a strong acid (e.g., nitric acid) and concentrations are measured using a range of spectroscopic techniques.57 Information on speciation is important for the understanding of the fate and toxicity of metals in waters.98 Recently developed passive sampling techniques allow a better understanding of the speciation of metals in the environment. Passive samplers are suitable for determining free hydrated metal ions and metal complexes with sufficiently high dissociation rates.99–104 Advances in the understanding of the speciation of metals in the aquatic environment have been achieved using the DGT. Hydrogels of varying pore size are used, which can exclude or restrict (on a size basis) the diffusion of large organic complexes into the device.99,100 Sampling selectivity can also be modified by varying the thickness of the hydrogel diffusion layer. Increasing the thickness allows the sampling of stable complexes since labile species will dissociate during the time required to diffuse across the layer.101,103 Different binding phases can also be used to modify selectivity. Li et al.105 investigated the effect of the binding strength (stability constant) of the sorption phase on the accumulation of metals. They investigated several binding phases, including Chelex 100 polyacrylamide hydrogel, poly(acrylamideco-acrylic acid) gel, poly(acrylamidoglycolic acid-co-acrylamide) gel, Whatman P-81 cellulose phosphate ion-exchange membrane, and poly(4-styrenesulfonate) solution. Tests conducted using solutions of metals spiked with ethylenediaminetetraacetic acid (EDTA) or humic acid suggested that the DGT measures only free metal ions and inorganic metal complexes. Field trials at both freshwater and seawater sites showed that the DGT-labile metal concentrations measured by devices fitted with different binding phases can be significantly different. This suggested that the DGT-labile metal fractions sequestered were dependent on the binding strength of the receiving phase. DGT devices fitted with different binding phases that can compete to varying extents with various natural complexing ligands can be utilized to measure metal speciation in natural waters.

3.3.6

ALGAL TOXINS

Mackenzie et al.72 developed a simple and sensitive sampler for monitoring toxic algal blooms and shellfish contamination. This involved the adsorption of biotoxins onto porous synthetic resin-filled sachets (solid-phase adsorption toxin tracking: SPATT bags) followed by their extraction and analysis. The technique measured pectenotoxins and okadaic acid complex toxins, the levels of which are increased in seawater during algal blooms. This approach is simpler than the analysis of shellfish tissue extracts. Time-integrated sampling provided an estimate of biotoxin accumulation in filter feeders, and the high sensitivity of the method provided an early warning of the potential of contamination. Recently, Fux et al.106 showed that divinylbenzene polymeric resins can be used as

56

Analytical Measurements in Aquatic Environments

sorption phases in SPATT samplers for the detection of the lipophilic marine toxins okadaic acid, and dinophysistoxin-1 from Prorocentrum lima. Kohoutek et al.107 used a modified POCIS fitted with a polycarbonate membrane and Oasis HLB sorbent for monitoring common and highly hazardous microcystins (cyanotoxins) in water. A seven-day exposure in the field was sufficient to detect the microcystins.

3.3.7 APPLICATIONS IN ECOTOXICITY ASSESSMENT A novel application is the use of extracts obtained from the elution of the sorption phase in bioassays to assess the ecotoxicity of accumulated pollutants. This has been attempted mainly with samplers used to sequester either nonpolar or polar organic chemicals.108 This approach overcomes some of the problems in obtaining samples suitable for testing the biological effects of low levels of pollutants present in water. When testing extracts are obtained from a sorption phase, solvent compatibility with the chosen bioassay is important. A number of solvents can be toxic, inhibitory, or immiscible, and sometimes solvent exchange is needed before an extract can be assayed. Several different bioassays have been used with extracts from samplers. These include Microtox®, Mutatox®, mixed-function oxygenase induction as 7-ethoxyresorufin-o-deethylase (EROD) activity, sister chromatid exchange, vitellogenin induction, enzyme-linked immunosorbent assay, Ames mutagenicity test, the yeast estrogen assay (YES-screen), and yeast androgen assay (YAS-screen).108–111 The use of these screening procedures can be a quick, cost-effective means of identifying problems that may otherwise require rigorous chemical analysis, resulting in greater expenditure of time and money.112 They may also have a contribution in improving risk assessment and in optimizing remediation measures. The following examples highlight how extracts from the sorbent phase or the sorbent phase itself can be used to help in the assessment of the ecotoxicity of surface water and groundwater. Rastall et al.113 used extracts from SPMDs in a bioassay-directed chemical analysis scheme for the detection and identification of bioconcentratable hydrophobic estrogen receptor agonists (ERA) at riverine sites in Germany and the United Kingdom. An aliquot of the extract was fractionated using a reverse-phase high-performance liquid chromatography (HPLC) method that was calibrated to provide an estimation of target analyte hydrophobicity. Each fraction was then tested in the YES screen to determine any estrogenic activity. This activity was plotted against HPLC retention time (i.e., a measure of compound hydrophobicity). In fractions where significant activity was found, an aliquot was subsequently analyzed by gas chromatography (GC)/mass spectrometry (MS) in an attempt to identify the compounds responsible for the observed estrogenic activity. The study indicated that improvements to the analytical methodology would be required in order to identify all of the ERAs or other target analytes present in the active fractions. This would increase the applicability of the method to risk assessment and water quality monitoring programs. Vermeirssen et al.111 used POCIS for sampling polar estrogens. Masses of estrogens accumulated in POCIS and concentrations of these compounds in spot samples were determined using the YES screen (being expressed as 17-b-estradiol equivalents). Chemical analysis of selected compounds was also performed using LC/MS. They found that data from spot sampling, passive sampling, and bioaccumulation in caged fish were correlated and provided comparable values. POCIS provided an integrated and biologically meaningful measure of estrogenicity in that it accumulated estrogens in a pattern similar to that of brown trout. A novel approach using the sorbent phase directly (with no extraction) in contact with cell lines from rainbow trout liver was developed by Schirmer et al.114 and Bopp et al.115 The cell lines were used to detect EROD activity from specific PAHs. A modified ceramic dosimeter (Toximeter sampler containing Biosilon 160–300 μm diameter polystyrene beads as the sorbent phase) was deployed for extended periods in groundwater known to be contaminated by PAHs. The response obtained using the cell lines incubated with Biosilon beads correlated with the concentrations of PAHs known to have EROD-inducing activity. The system is versatile as other cell lines can be used depending on the toxicological response of interest.

Application of Passive Sampling Techniques

3.3.8

57

APPLICATIONS IN BIOMONITORING

Historically, biota have been used to obtain information on biologically relevant concentrations of pollutants in water. Various test organisms (e.g., mussels and fish) can be used depending on the water body being investigated. Test biota can be deployed for extended periods of time during which they bioaccumulate pollutants from the surrounding water. Analysis of tissues or lipid extracts can give an indication of the equilibrium concentration of waterborne contamination. Several factors can influence the levels of pollutants accumulated: they include metabolism, depuration rates, excretion, stress, viability, and the condition of test organisms. These factors can lead to uncertainty associated with the data. Furthermore, the extraction of analytes from the tissue of animals prior to instrumental analysis is complex and time-consuming. In spite of these difficulties, mussels have been extensively used (e.g., the Dutch National Institute of Coastal and Marine Management “mussel watch” program) in the monitoring of hydrophobic contaminants in both freshwater and marine environments16 and a large historical dataset of pollutant levels is available. Recently, Smedes16 investigated whether passive sampling devices could be used to give similar information on biologically available concentrations of hydrophobic compounds (e.g., PAHs and PCB). The samplers comprised silicone rubber sheets (9.5 cm ¥ 5.5 cm ¥ 0.5 cm) spiked with a range of PRCs and were deployed in tandem with mussels (Mytilus edulis) for six weeks at several coastal sampling stations in the Netherlands. Results showed there was a close relationship (even over different seasons) between the concentrations found in mussels and those derived from the passive samplers. However, for the very hydrophobic compounds, there was some uncertainty as to whether equilibrium had been achieved by the end of the deployment period. The use of passive samplers shows considerable promise as an alternative to the use of biota in routine monitoring programs.

3.4

QUALITY ASSURANCE, QUALITY CONTROL AND VALIDATION

The application of appropriate quality control (QC) measures is essential in environmental monitoring projects using passive samplers. This is important in both sampler exposure and the subsequent sampler processing and instrumental analysis. In general, quality assurance (QA) measures should be implemented throughout all procedures including preparation, handling (transportation, deployment, and retrieval), and storage processes in accordance with ISO 5667-14.116 The level of QC applied to passive sampling will vary depending on the project objectives and procedures involved. The recently published British Standards Institute Publicly Available Specification (BSI PAS-61) on the use of passive samplers for monitoring pollutants in water gives helpful advice on this issue.117 QC samples should address such issues as the purity of materials used to construct the device, and potential contamination during preparation, transport, deployment, retrieval, and subsequent storage. Furthermore, QC protocols are required for analyte extraction, further processing (preconcentration and isolation operations), and instrumental analysis. The samples related to the control requirements for passive sampler studies include fabrication controls, reagent blanks, field controls, and sampler recovery spikes. Fabrication controls are QC samples used to record contamination during manufacture, laboratory storage, processing, and analytical procedures. Field controls are QC samples used to record any contamination during transportation, deployment, and retrieval. In some cases, samplers spiked with PRCs serve as a special type of QC sample. These provide information about in situ uptake kinetics and reduce bias in the estimation of TWA concentrations when laboratory-derived calibration data are applied to the situation in the field.42 An example of the investigation of QC issues associated with the use of passive samplers has been published by DeVita and Crunkilton.118 The results of their study showed that QC measures applied to SPMDs met or surpassed conventional guidelines (e.g., EPA Method 610 for PAHs in water) in terms of both precision and accuracy. Only a small number of interlaboratory proficiency tests, required for full method validation, have been performed. In 2006, the International Council for the Exploration of the Sea (ICES)

58

Analytical Measurements in Aquatic Environments

initiated a trial survey and intercalibration exercise for passive sampling involving 13 participating laboratories.119 The study sampled freely dissolved hydrophobic contaminants in water and sediment. For water, only PDMS sheet passive samplers were used. In parallel, sediment samples were collected at the same locations and equilibrated with passive samplers in the laboratory. Analyses of the samplers used in the water and sediment studies by both the participating laboratories and a central reference laboratory allowed the trial to act as an analytical intercalibration study. Currently, only preliminary results on freely dissolved concentrations of phenanthrene and PCB-153 in seawater and sediment pore water samples at the 13 test sites across Europe have been reported.119 This technique enabled the detection of nonpolar analytes in water at low pg L-1 levels. Field studies in which the results obtained with passive samplers are compared with those obtained with conventional sampling techniques also increase the body of evidence that is available to underpin acceptance of the validity of passive sampling within a regulatory framework. However, assessing the accuracy of measurements made by passive samplers against other techniques may prove difficult, as the results may not be directly comparable. One possible reason for differences sometimes observed between spot sampling and passive sampling data is that the discontinuous spot samples may be taken at time points when concentrations of a pollutant were higher or lower than average and large fluctuations may occur in the intervals between samples. When the conventional sampling approach is used, any change in ambient concentration during the intervals between samples is undetected, but passive samplers can reflect such events. Spot (bottle or grab) sampling measures either total concentrations of pollutants or concentrations remaining in the sample after filtration (e.g., through a 0.45-μm filter). In comparison, passive samplers sequester only that fraction of contaminants that can diffuse into the sorption phase. This fraction is sometimes referred to as the freely available or bioavailable fraction. This can be misleading as this fraction will vary according to the design of the device. For example, samplers can be fitted with either porous or nonporous membranes for different applications. In the case of the DGT, different pore size gels (open pore or restricted pore) can be used to measure different molecular size fractions of metals and this can help in speciation studies.120 One approach to help overcome this disparity between spot and passive sampling data is to use additional water quality data. If average values of DOC, suspended particulate matter, and total organic carbon content are known, it may be possible to estimate the total concentration using empirical relationships that describe the distribution of a chemical between the different phases that may be present in an environmental water sample.121 There is, however, uncertainty associated with this approach, as a number of assumptions are made in the calculations and a better understanding of the partitioning behavior of priority pollutants between the different phases is needed. Several studies have compared the accuracy of pollutant concentrations measured using passive samplers with those obtained by active sampling methods. Ellis et al.122 found close agreement between the concentrations of a number of organochlorine pesticides measured using SPMDs and those measured in spot water samples processed through a tangential-flow ultrafilter. However, many compounds detected in SPMD extracts were not found in the filtered spot samples. Rantalainen et al.123 compared the levels and congener profiles of polychlorinated dibenzo-p-dioxins, dibenzofurans, and non-o-chlorinated biphenyls in the water column measured using SPMDs with those collected by an Infiltrex® resin column sampler. Both the SPMD and Infiltrex sampler data were similar. Zeng et al.124 found very good agreement between the results obtained using an equilibrium passive sampling device based on SPME and those obtained using an Infiltrex 100 in situ largevolume extractor for a range of PCBs and organochlorine pesticides. Axelman et al.125 compared concentrations of dissolved PAHs at a site contaminated by discharges from an aluminum smelter. Measurements using SPMDs were similar to those obtained using an on-line filtration system. The PAH concentrations calculated from SPMD data showed a systematic deviation from the active sampling method that increased with compound hydrophobicity. The method used for calculating water concentrations from SPMD data was implicated as a potential source of systematic error. Several other field validation trials for measuring organic pollutants using different designs of

Application of Passive Sampling Techniques

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passive sampler (Chemcatcher,27,56,126,127 ceramic dosimeters,54,114,128 POCIS,36,45 SPMDs,129,130 SPME,131 TRIMPS,132 and MESCO44) alongside frequent spot sampling have been reported. For inorganic pollutants, several field studies comparing the Chemcatcher and DGT with other sampling methods and theoretical speciation models have been undertaken.120,133–139

3.5 USE OF PASSIVE SAMPLING IN REGULATORY MONITORING Until recently, checking water quality compliance with the regulatory provisions has been based on the chemical analysis of spot samples of water taken at a defined frequency. In Europe, the implementation of the European Union’s Water Framework Directive (WFD, 2000/60/EC)140 has resulted in an urgent need for cost-efficient monitoring tools that can provide the required information for the assessment of water quality. This legislation applies to the management of all water bodies (surface, ground, coastal, and lakes) with a target aim of achieving good water quality status by 2015. Three different monitoring approaches (surveillance, operational, and investigative) are defined within the Framework.140 The European Union (EU) assessment of water quality according to the provisions of the WFD includes the measurement of a number of quality elements and an evaluation of the presence of priority pollutants in these various water bodies. Based on the levels of priority substances measured, the water body is classified as having either “good” or “bad” chemical status. For the classification of the chemical status, environmental quality standards (EQS) have been set for priority organic pollutants in surface water. These include annual average and maximum acceptable concentration quality standards (AA-QS and MAC-QS, respectively). For compliance checking, total concentrations of priority organic pollutants in water are compared with EQS values. For heavy metals, the concentrations determined in filtered (through a 0.45-μm filter) samples of water are compared with EQS values. For a meaningful comparison with EQS, monitoring data should be representative of the pollutant levels in the water body. Under the WFD, current monitoring practice is based on the regular (in most cases once a month) collection of spot water samples and their subsequent analysis for defined priority substances. This approach suffers from several drawbacks. Spot samples provide concentrations of pollutants only at the moment of sampling. Thus in water bodies characterized by marked temporal and spatial variability there is an increased risk of a false classification of the chemical status.141 Further, EQS values for many priority compounds are very low (e.g., tributyltin cation, PAHs, and polybrominated diphenyl ethers) and the laboratory methods commonly used for the analysis of spot samples of water are often not sensitive enough to fulfill the required minimum performance criteria. Moreover, several studies have demonstrated a decrease in method reproducibility with decreasing concentrations of organic pollutants.142 Therefore, conventional bottle sampling followed by instrumental analysis for the measurement of trace levels of organic and metal contaminants has severe limitations in terms of achievable limits of detection, reproducibility, confidence in the results obtained, and the ability to use the data on their own for decision-making within the context of the WFD.141 The WFD does not specify the techniques to be used for the monitoring of quality elements, including priority chemical substances. Among the alternative technologies available, passive samplers have the potential to be used in various regulatory monitoring programs aimed at assessing the levels of chemical pollutants. This has been recognized in the recently published technical guidance document for monitoring chemical substances within the context of the WFD.143,144 A number of possible applications of passive sampling in the regulatory monitoring of surface waters were identified, and these scenarios were based on field demonstrations undertaken as part of the EU-funded SWIFT-WFD project.141,145 However, passive samplers can only be used in surveillance and operational monitoring if they meet the Commission’s requirements concerning defined minimum performance criteria for chemical monitoring methods and the quality of the analytical results.146 Passive samplers can be used alongside spot sampling in order to corroborate or contradict the data obtained. This approach can provide additional “weight-of-evidence” in water bodies where concentrations of contaminants are expected to fluctuate widely with time. Since one of the primary objectives of the WFD is the assessment of representative concentrations of pollutants in water

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bodies, the measurement of TWA concentrations over a period of several weeks using passive samplers seems to be a promising approach. Passive samplers can also effectively sample large volumes of water (the equivalent of tens of liters) over the deployment period. Therefore, it is possible at reasonable cost to measure much lower aqueous concentrations of pollutants than is possible using low-volume spot sampling procedures. This is particularly important for the very hydrophobic priority pollutants, for example, polybrominated diphenyl ethers, high-molecular-weight PAHs, some organochlorine pesticides, and organotin compounds. An additional use of passive samplers is in investigative monitoring. Samplers can be deployed at a number of sites to detect and hence locate unknown sources of pollution. Besides the advantages that passive sampling may offer, it is important to recognize that in many cases these devices measure a different fraction of contaminants than that defined for the checking of EQS compliance within the WFD. This becomes especially important when monitoring very hydrophobic chemicals (log KOW > 4), where a large fraction of the total amount present in a spot water sample is bound to colloids and particles. In contrast, most passive samplers used for monitoring hydrophobic compounds (e.g., SPMD, Chemcatcher, and silicone materials) measure only the truly dissolved fraction of these chemicals. Nevertheless, for compliance checking, reliable estimation of the relevant (total or filtered) concentration from passive sampling data should be possible using additional information (e.g., DOC level and concentration of suspended particulate matter) on water quality at the monitoring site. These data can be used in models that describe the distribution of chemicals between water, colloidal, and particulate matter phases. With the exception of extreme situations (water bodies with a very high colloidal or particulate matter content), such calculations could provide a “worst case estimate” (the maximum concentration of a priority pollutant present in the water during the sampler deployment). If such estimates fall below the EQS limit, the water body would be classified by a “good” chemical status. When sampling trace concentrations of pollutants, the level of uncertainty in this approach will be lower than that associated with spot sampling techniques. However, the validity of this approach in compliance monitoring still needs to be demonstrated before it can be accepted by regulators, water quality managers, and other end users of the data.

3.6 FUTURE TRENDS There are several future trends for the development of passive sampling techniques. The first is the development of devices that can be used to monitor “emerging” environmental pollutants. Recently, attention has shifted from hydrophobic persistent organic pollutants to compounds with a mediumto-high polarity, for example, polar pesticides, pharmaceuticals, and personal care products.82,147,148 Novel materials will need to be tested as selective receiving phases (e.g., ionic liquids, molecularly imprinted polymers, and immunoadsorbents), together with membrane materials that permit the selective diffusion of these chemicals. The sample extraction and preconcentration methods used for these devices will need to be compatible with LC-MS analytical techniques. The second trend is toward miniaturization of devices. Small devices are usually less expensive to use because of the lower costs of materials needed for their preparation and the reduced equipment requirements for their deployment. Lower volumes of solvents and reagents are consumed during their subsequent processing. Small samplers also offer the advantage of easy transportation to and from the sampling site. As miniaturized devices should not deplete the bulk matrix, they can be used in situations where space, volume, and the flow of water are limited, for example, in groundwater boreholes.149 This trend can benefit from recent achievements in the area of solvent-free sample preparation techniques. Passive samplers based on in situ analyte preconcentration (e.g., SPME or stir-bar sorptive extraction) allow sample processing using thermal desorption-GC22 or solvent microextraction followed by HPLC.150 However, the practical application of SPME-based techniques in the in situ sampling of trace levels of aqueous contaminants still requires further enhancement in terms of robustness and sensitivity.

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A major challenge in the future development of the technology is the calibration of devices to enable the quantitative assessment of the levels of pollutants present in water. A full evaluation of the various factors (e.g., water temperature, water turbulence, salinity, DOC level, pH, biofouling, and the presence of complex mixtures of contaminants) that may affect the performance of samplers is essential. Further steps are necessary for the reduction or control of the known impacts of environmental variables on sampler performance. For samplers where analytes are accumulated in the receiving phase by absorption mechanisms, PRCs have been successfully employed for improving the accuracy of the measurement of TWA concentrations of contaminants in the field. However, a better understanding of accumulation kinetics in samplers fitted with adsorbent-type receiving phases remains a challenge and requires further research. Robust calibration data for passive sampling devices used in monitoring trace metals are essential for quantification of the various metal species and complexes found in different aquatic environments. This requires knowledge of the uptake kinetics of different metal moieties. Configuration of specific devices for monitoring well-defined fractions and species of metals will enhance their potential as regulatory tools and help to overcome some of the current limitations of spot sampling. The ability to model uptake parameters for passive samplers based on the physicochemical properties of the sampled compounds and their interactions with materials used in the construction of devices is also important. This may help to reduce the need for extensive laboratory-based calibration experiments. Further work is needed to model the performance of passive samplers when concentrations of pollutants fluctuate widely. This is important where a lag phase in the response of the sampler can affect the efficiency of the detection of a short pollution event. A better understanding of the factors determining the responsiveness of devices to changing water concentrations will help to improve sampler design in the future. Development of biomimetic devices capable of simulating the accumulation of toxic chemicals in tissues of aquatic organisms will enable a reduction in the use of biomonitoring procedures in routine monitoring programs. It will also decrease the uncertainty associated with the data obtained, as this is based on highly variable samples of biological material. The combination of the deployment of passive samplers followed by the biological testing of sampler extracts with the aim of detecting and subsequently identifying toxicologically relevant compounds offers much potential. This approach can provide information concerning the relative toxicological significance of waterborne contaminants and hence help to improve risk assessments for different water bodies. Finally, further development of QA/QC, method validation schemes, and standards for the use of passive sampling devices is urgently needed. Successful demonstration of the performance of passive samplers alongside conventional sampling schemes will help to facilitate the acceptance of passive sampling in routine regulatory monitoring programs in the future.

ACKNOWLEDGMENTS We acknowledge the financial support of the European Commission (Contracts EVK1-CT-200200119; http://www.port.ac.uk/stamps/ and SSPI-CT-2003-502492; and http://www.swift-wfd.com/) and the Slovak Research and Development Agency (Contract SK-ZA-0006-07).

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A comparison of concentration levels in semipermeable membrane devices (SPMDs), blue mussels (Mytilus edulis) and water samples. J. Environ. Monit. 4: 280–283. 95. Harman, C., O. Bøyum, K.E. Tollefsen, K. Thomas, and M. Grung. 2008. Uptake of some selected aquatic pollutants in semipermeable membrane devices (SPMDs) and the polar organic chemical integrative sampler (POCIS). J. Environ. Monit. 10: 239–247. 96. Aguilar-Martínez, R., R. Greenwood, G.A. Mills, B. Vrana, M.A. Palacios-Corvillo, and M.M. GómezGómez. 2008. Assessment of Chemcatcher passive sampler for the monitoring of inorganic mercury and organotin compounds in water. Int. J. Environ. Anal. Chem. 88: 75–90. 97. Warnken, K.W., H. Zhang, and W. Davison. 2007. In situ monitoring and dynamic speciation measurement in solution using DGT. In: R. Greenwood, G.A. Mills, and B. Vrana (eds), Passive Sampling Techniques in Environmental Monitoring, pp. 251–278. Amsterdam: Elsevier. 98. Buffle, J. and M.-L. Tercier-Waeber. 2005. Voltammetric environmental trace-metal analysis and speciation: From laboratory to in situ measurements. Trends Anal. Chem. 24: 172–191. 99. Zhang, H. and W. Davison. 2000. Direct in situ measurements of labile inorganic and organically bound metal species in synthetic solutions and natural waters using diffusive gradients in thin films. Anal. Chem. 72: 4447–4457. 100. Zhang, H. and W. Davison. 2001. In situ speciation measurements. Using diffusive gradients in thin films (DGT) to determine inorganically and organically complexed metals. Pure Appl. Chem. 73: 9–15. 101. Scally, S., W. Davison, and H. Zhang. 2003. In situ measurements of dissociation kinetics and labilities of metal complexes in solution using DGT. Environ. Sci. Technol. 37: 1379–1384. 102. Scally, S., H. Zhang, and W. Davison. 2004. Measurements of lead complexation with organic ligands using DGT. Aust. J. Chem. 57: 925–930. 103. Li, W., H. Zhao, P.R. Teasdale, and F. Wang. 2005. Trace metal speciation measurements in waters by the liquid binding phase DGT device. Talanta 67: 571–578.

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104. Garmo, O.A., O., Royset, E., Steinnes, and T.P. Flaten. 2003. Performance study of diffusive gradients in thin films for 55 elements. Anal. Chem. 75: 3573–3580. 105. Li, W., H. Zhao, P.R. Teasdale, R. John, and F. Wang. 2005. Metal speciation measurement by diffusive gradients in thin films technique with different binding phases. Anal. Chim. Acta 533: 193–202. 106. Fux, E., C. Marcaillou, F. Mondeguer, R. Bire, and P. Hess. 2008. Field and mesocosm trials on passive sampling for the study of adsorption and desorption behaviour of lipophilic toxins with a focus on OA and DTX1. Harmful Algae 7: 574–583. 107. Kohoutek, J., P. Babica, L. Blaha, and B. Marsalek. 2008. A novel approach for monitoring of cyanobacterial toxins: Development and evaluation of the passive sampler for microcystins. Anal. Bioanal. Chem. 390: 1167–1172. 108. Sabaliunas, D., J.R. Lazutka, and I. Sabaliuniene. 2000. Acute toxicity and genotoxicity of aquatic hydrophobic pollutants sampled with semipermeable membrane devices. Environ. Pollut. 109: 251–265. 109. Johnson, B.T., J.N. Huckins, J.D. Petty, and R.C. Clark. 2000. Collection and detection of lipophilic chemical contaminants in water, sediment, soil, and air—SPMD-TOX. Environ. Toxicol. 15: 248–252. 110. Johnson, B.T., J.D. Petty, J.N. Huckins, K. Lee, and J. Gauthier. 2004. Hazard assessment of a simulated oil spill on intertidal areas of the St. Lawrence River with SPMD-TOX. Environ. Toxicol. 19: 329–335. 111. Vermeirssen, E.L.M., O. Korner, R. Schonenberger, M.J.F. Sutter, and P. Burkhardt-Holm. 2005. Characterization of environmental estrogens in river water using a three pronged approach: Active and passive water sampling and the analysis of accumulated estrogens in the bile of caged fish. Environ. Sci. Technol. 39: 8191–8198. 112. Petty, J.D., J.N. Huckins, and D.A. Alvarez, et al. 2004. A holistic passive integrative sampling approach for assessing the presence and potential impacts of waterborne environmental contaminants. Chemosphere 54: 695–705. 113. Rastall, A.C., D. Getting, J. Goddard, D.R. Roberts, and L. Erdinger. 2006. A biomimetic approach to the detection and identification of estrogen receptor agonists in surface waters using semipermeable membrane devices (SPMDs) and bioassay-directed chemical analysis. Environ. Sci. Pollut. Res. 13: 256–267. 114. Schirmer, K., S. Bopp, and J. Gerhardt. 2007. Use of passive sampling devices in toxicity assessment of groundwater. In: R. Greenwood, G.A. Mills, and B. Vrana (eds), Passive Sampling Techniques in Environmental Monitoring, pp. 393–405. Amsterdam: Elsevier. 115. Bopp, S.K., M.S. Mclachlan, and K. Schirmer. 2007. Passive sampler for combined chemical and toxicological long-term monitoring of groundwater: The ceramic taximeter. Environ. Sci. Technol. 41: 6868–6876. 116. ISO 5667-14. 1998. Water quality—sampling. Part 14: Guidance on quality assurance of environmental water-sampling and handling. 117. British Standards Institute (BSI). Publicly available specification: Determination of priority pollutants in surface water using passive sampling (PAS-61), May 2006. 118. DeVita, W.M. and R.L. Crunkilton. 1998. Quality control associated with use of semipermeable membrane devices. Environ. Toxicol. Risk Assess. 1333: 237–245. 119. www.passivesampling.net/. 120. Sigg, L., F. Black, J. Buffle, et al. 2006. Comparison of analytical techniques for dynamic trace metal speciation in natural freshwaters. Environ. Sci. Technol. 40: 1934–1941. 121. Burkhard, L.P. 2000. Estimating dissolved organic carbon partition coefficients for nonionic organic chemicals. Environ. Sci. Technol. 34: 4663–4667. 122. Ellis, G.S., J.N. Huckins, C.E. Rostad, C.J. Schmitt, J.D. Petty, and P. MacCarthy. 1995. Evaluation of lipid-containing semipermeable membrane devices (SPMDs) for monitoring organochlorine contaminants in the upper Mississippi River. Environ. Toxicol. Chem. 14: 1875–1884. 123. Rantalainen, A.L., M.G. Ikonomou, and I.H. Rogers. 1998. Lipid-containing semipermeable-membrane devices (SPMDs) as concentrators of toxic chemicals in the lower Fraser River, British Columbia. Chemosphere 37: 1119–1138. 124. Zeng, E.Y., D. Tsukada, and D.W. Diehl. 2004. Development of solid-phase microextraction-based method for sampling of persistent chlorinated hydrocarbons in an urbanized coastal environment. Environ. Sci. Technol. 38: 5737–5743. 125. Axelman, J., K. Naes, C. Näf, and D. Broman. 1999. Accumulation of polycyclic aromatic hydrocarbons in semipermeable membrane devices and caged mussels (Mytilus edulis L.) in relation to water column phase distribution. Environ. Toxicol. Chem. 18: 2454–2461.

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126. Vrana, B., G.A. Mills, M. Kotterman, P. Leonards, K. Booij, and R. Greenwood. 2007. Modelling and field application of the Chemcatcher passive sampler calibration data for the monitoring of hydrophobic organic pollutants in water. Environ. Pollut. 145: 895–904. 127. Schäfer, R.B., A. Paschke, B. Vrana, R. Mueller, and M. Liess. 2008. Performance of the Chemcatcher® passive sampler when used to monitor 10 polar and 3 semi-polar pesticides in 16 Central European streams, and comparison with two other sampling methods. Water Res. 42: 2707–2717. 128. Bopp, S., H. Weiss, and K. Schirmer. 2005. Time-integrated monitoring of polycyclic aromatic hydrocarbons (PAHs) in groundwater using the ceramic dosimeter passive sampling device. J. Chromatogr. A 1072: 137–147. 129. Luellen, D.R. and D. Shea. 2002. Calibration and field verification of semipermeable membrane devices for measuring polycyclic aromatic hydrocarbons in water. Environ. Sci. Technol. 36: 1791–1797. 130. Vrana, B., A. Paschke, P. Popp, and G. Schüürmann. 2001. Use of semipermeable membrane devices (SPMDs): Determination of bioavailable organic contaminants in the industrial region of Bitterfeld, Saxony-Anhalt, Germany. Environ. Sci. Pollut. Res. 8: 27–34. 131. Ouyang, G., W. Zhao, L. Bragg, Z. Qin, M. Alaee, and J. Pawliszyn. 2007. Time-weighted average water sampling in Lake Ontario with solid-phase microextraction passive samplers. Environ. Sci. Technol. 41: 4026–4031. 132. Hyne, R.V., F. Pablo, M. Aistrope, A.W. Leonard, and N. Ahmad. 2004. Comparison of time-integrated pesticide concentrations determined from field-deployed passive samplers with daily river-water extractions. Environ. Toxicol. Chem. 23: 2090–2098. 133. Alfaro-De la Torre, M.C., P.Y. Beaulieu, and A. Tessier. 2000. In situ measurement of trace metals in lake water using the dialysis and DGT techniques. Anal. Chim. Acta 418: 53–68. 134. Gimpel, J., H. Zhang, W. Davison, and A.C. Edwards. 2003. In situ trace metal speciation in lake surface waters using DGT, dialysis and filtration. Environ. Sci. Technol. 37: 138–146. 135. Zhang, H. 2004. In-situ speciation of Ni and Zn in freshwaters: Comparison between DGT measurements and speciation models. Environ. Sci. Technol. 38: 1421–1427. 136. Meylan, S., N. Odzak, R. Behra, and L. Sigg. 2004. Speciation of copper and zinc in natural freshwater: Comparison of voltammetric measurements, diffusive gradients in thin films (DGT) and chemical equilibrium models. Anal. Chim. Acta 510: 91–100. 137. Allan, I.J., J. Knutsson, N. Guigues, G.A. Mills, A.-M. Fouillac, and R. Greenwood. 2007. Evaluation of the Chemcatcher and DGT passive samplers for monitoring metals with highly fluctuating water concentrations. J. Environ. Monit. 9: 672–681. 138. Dunn, R.J.K., P.R. Teasdale, J. Warnken, and J.M. Arthur. 2007. Evaluation of the in situ, time-integrated DGT technique by monitoring changes in heavy metal concentrations in estuarine waters. Environ. Pollut. 148: 213–220. 139. Unsworth, E.R., K.W. Warnken, and H. Zhang, W. Davison, F. Black, J. Buffle, J. Cao, et al. 2006. Model predictions of metal speciation in freshwaters compared to measurements by in situ techniques. Environ. Sci. Technol. 40: 1942–1949. 140. Directive 2000/60/EC of the European Parliament and of the Council of October 23, 2000, establishing a framework for Community action in the field of water policy. Off. J. Eur. Comm. L327: 1. 141. Allan, I.J., B. Vrana, R. Greenwood, G.A. Mills, J. Knutsson, A. Holmberg, N. Guigues, A.M. Fouillac, and S. Laschi. 2006. Strategic monitoring for the European Water Framework Directive. Trends Anal. Chem. 25: 704–715. 142. Coquery, M., A. Morin, A. Becue, and B. Lepot. 2005. Priority substances of the European Water Framework Directive: Analytical challenges in monitoring water quality. Trends Anal. Chem. 24: 117–127. 143. Quevauviller, P., U. Borchers, and B.M. Gawlik. 2007. Coordinating links among research, standardisation and policy in support of water framework directive chemical monitoring requirements. J. Environ. Monit. 9: 915–923. 144. WFD chemical monitoring guidance for surface water. Available at http://circa.europa.eu/Public/irc/env/ wfd/library?l=/framework_directive/chemical_monitoring/technical_2007pdf/_EN_1.0_&a=d. 145. Allan, I.J., B. Vrana, R. Greenwood, G.A. Mills, B. Roig, and C.A. Gonzalez. 2006. “Toolbox” for biological and chemical monitoring requirements for the European Union’s Water Framework Directive. Talanta 69: 302–322. 146. Commission of the European Communities. Commission directive laying down, pursuant to Directive 2000/60/EC of the European Parliament and of the Council, technical specifications for chemical analysis and monitoring of water status. Draft version of March 7, 2008. 147. Alvarez, D.A., J.D. Petty, J.N. Huckins, T.L. Jones-Leep, D.T. Getting, J.P. Goddard, and S.E. Manahan. 2004. Development of a passive, in situ, integrative sampler for hydrophilic organic contaminants in aquatic environments. Environ. Toxicol. Chem. 23: 1640–1648.

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148. Alvarez, D.A., P.E. Stackelberg, J.D. Petty, et al. 2005. Comparison of a novel passive sampler to standard water-column sampling for organic contaminants associated with wastewater effluents entering a New Jersey stream. Chemosphere 61: 610–622. 149. Richardson, S.D. and T.A. Ternes. 2005. Water analysis: Emerging contaminants and current issues. Anal. Chem. 77: 3807–3838. 150. Popp, P., C. Bauer, M. Moder, and A. Paschke. 2000. Determination of polycyclic aromatic hydrocarbons in waste water by off-line coupling of solid-phase microextraction with column liquid chromatography. J. Chromatogr. A 897: 153–159.

4

Modern Techniques of Analyte Extraction Thaer Barri and Jan-Åke Jönsson

CONTENTS 4.1 4.2

Introduction ........................................................................................................................ Modern Miniaturized Nonmembrane-Based Extraction Techniques ................................ 4.2.1 Miniaturized Liquid-Phase Extraction Techniques ................................................ 4.2.1.1 Background .............................................................................................. 4.2.1.2 Dynamic Liquid-Phase Microextraction ................................................. 4.2.1.3 Continuous-Flow Microextraction ........................................................... 4.2.1.4 Dispersive Liquid–Liquid Microextraction ............................................. 4.2.2 Miniaturized SPE Techniques ................................................................................ 4.2.2.1 Fiber-in-Tube SPE .................................................................................... 4.2.2.2 Microextraction in a Packed Syringe ....................................................... 4.2.2.3 Inside-Needle SPE ................................................................................... 4.2.3 Solid-Phase Microextraction .................................................................................. 4.2.3.1 Calibration in SPME ................................................................................ 4.2.3.2 Recent Trends in SPME Applications ...................................................... 4.2.4 Stir Bar Sorptive Extraction ................................................................................... 4.2.4.1 SBSE Development .................................................................................. 4.2.4.2 SBSE Modes of Operation ....................................................................... 4.3 Analytical Techniques Based on Nonporous Polymeric Membranes ................................ 4.3.1 Membrane Inlet (Introduction) Mass Spectrometry ............................................... 4.3.2 Membrane Extraction with Sorbent Interface ........................................................ 4.3.3 Membrane-Assisted Solvent Extraction ................................................................. 4.4 Analytical Techniques Based on the Use of Liquid Membranes ........................................ 4.4.1 Supported Liquid Membrane (SLM) Extraction .................................................... 4.4.1.1 SLM Extraction Principle ........................................................................ 4.4.1.2 SLM Unit and System Configurations ..................................................... 4.4.1.3 Transport Mechanisms in SLM ............................................................... 4.4.1.4 Selectivity in SLM ................................................................................... 4.4.1.5 Equilibrium Sampling Through SLM ..................................................... 4.4.2 Microporous Membrane Liquid–Liquid Extraction ............................................... 4.4.2.1 MMLLE Principle ................................................................................... 4.4.2.2 Miniaturization, Automation, and Hyphenation of MMLLE .................. 4.4.3 Two-Phase HF-LPME ............................................................................................ 4.4.3.1 Development of Two-Phase HF-LPME ................................................... 4.4.3.2 Automation of Two-Phase HF-LPME ..................................................... 4.5 Summary and Future Outlook ............................................................................................ Acronyms and Abbreviations ....................................................................................................... References ....................................................................................................................................

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INTRODUCTION

The Rio Declaration on Environment and Development in 1992 emphasized the sustainable development of human life. The output of the Rio summit clearly outlined and recommended several principles that all countries are advised to recognize. A couple of these principles stressed the need for the reduction and elimination of unsustainable patterns of production and consumption of substances that cause severe environmental degradation or are found to be harmful to human health.1 The role of chemistry in human sustainability, bearing in mind the global demand for environmentally benign chemical processes and products, stems from providing unique and cost-effective chemical procedures for pollution prevention. From this role, the concept of green chemistry has emerged and has been touching upon all aspects of chemical processes, starting from simple environmentally friendly chemical tests and ending with biofuel production scale-up processes. The green aspects of a chemical protocol stand upon 12 principles that aim at reducing or eliminating the use or generation of hazardous substances in the design, manufacture, analysis, and applications of chemical products.2 The discipline “green analytical chemistry” is concerned with the elimination of solvents in chemical processes or the replacement of hazardous solvents with environmentally friendly ones. The green analytical procedures used nowadays in modern analyte extraction techniques are normally designed by system miniaturization,3 which in turn promotes procedure automation and hyphenation to the separation techniques.4 These modern sample preparation procedures utilize different formats of mainly a miniaturized liquid phase, solid phase, sorptive phase, a synthetic polymeric nonporous membrane phase, or a liquid membrane phase, that is, a liquid supported in a porous membrane material.

4.2 MODERN MINIATURIZED NONMEMBRANE-BASED EXTRACTION TECHNIQUES The huge leap in the development of many dedicated analytical instruments has put the ball in the analytical chemists’ court, as sample preparation is still considered the bottleneck of sample extraction and analysis. The primary aim of sample preparation is the cleanup and concentration of the analytes of interest, rendering them in a form that is compatible with the analytical instrument. In this regard, the shortcomings of liquid–liquid extraction (LLE) are well known (such as the consumption of huge amounts of potentially toxic organic solvents), and have been the motivation toward developing new, alternative procedures. Solid-phase extraction (SPE) employing an adsorptive solid extractive phase in the form of a cartridge or a disk has, on the other hand, significantly reduced the amount of solvents utilized compared with LLE. Therefore, SPE has been shown to be a better choice in many extraction situations and has gained popularity in spite of its high-price products. However, SPE still generally consumes significant volumes of solvent and an extra concentration step of the extract is usually needed to bring the volume down. SPE can be automated, but the additional complexity in design and the high cost make the technique difficult to accept; indeed, in many cases, the technique is even unaffordable. As a corollary to this, more direct sample preparation procedures have been the pursuit of many scientists, who believe that miniaturization of analytical techniques can be a key solution to many of the unwanted drawbacks of LLE and SPE. Currently, several miniaturized extraction systems have been investigated, which are based primarily on utilizing downsized liquid, solid, or membrane extraction phases.

4.2.1

MINIATURIZED LIQUID-PHASE EXTRACTION TECHNIQUES

Trends in miniaturization of liquid-phase extraction procedures have been spawned and given many different names; they refer to the same principle but with different, or sometimes the same,

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configurations. For example, the terms “solvent microextraction,” “liquid-phase microextraction,” “single-drop microextraction,” “liquid–liquid microextraction,” and even “liquid–liquid–liquid microextraction” are not uncommon in the liquid-based sample preparation literature. The principle of these techniques first stemmed from the pioneering paper “Analytical Chemistry in a Drop. Solvent Extraction in a Microdrop” published by Liu and Dasgupta in 1996 as an accelerated article in Analytical Chemistry. The authors skillfully described a drop-in-drop microextraction system in which an organic microdrop (1.3 mL) was suspended inside a flowing aqueous drop containing the analyte to be extracted.5 4.2.1.1 Background Dasgupta’s paper inspired researchers to design new analytical techniques. For instance, Jeannot and Cantwell employed a Teflon rod as a support for hanging a small drop of n-octane (8 mL). The probe (drop-attached rod) was immersed in a stirred aqueous sample for extraction. The probe was then withdrawn and the organic phase sucked out by a microsyringe needle that was afterwards used for gas chromatography (GC) injection. The technique was called solvent microextraction (SME), which, in that work, was thoroughly elaborated with regard to its kinetics, giving estimates of mass transfer and diffusion coefficients.6 The work described by Jeannot and Cantwell implied utilizing two different apparatuses for two different steps; a Teflon rod supporting the drop (for extraction) and a microsyringe (for injection of the extract into the analytical instrument). The work was further developed by incorporating only a microsyringe for extraction (as solvent drop holder) and extract injection (as sample injector) into the analytical instrument.7 To enhance extraction efficiency in the SME system (also called single-drop microextraction [SDME]), He and Lee developed a procedure termed liquid-phase microextraction (LPME),8,9 which, in its static mode, resembles the SME system. 4.2.1.2 Dynamic Liquid-Phase Microextraction LPME can also be run in a dynamic mode in which a specified volume of an aqueous sample containing the analytes is repeatedly withdrawn into and expelled from a microsyringe barrel preloaded with a microliter-volume organic solvent. The process is performed several times within a short period.8-10 The microsyringe here functions as a microseparatory apparatus for extraction and as an injector into a GC. Therefore, after a preset extraction time, the sample is expelled from the syringe barrel and the organic solvent is injected into the GC. As compared to the static mode, dynamic liquid-phase microextraction (DLPME) demonstrated that after each sample withdrawal by the microsyringe plunger, a thin solvent film is formed on the interior surface of the syringe barrel. In addition to the considerable agitation of the two phases, facilitated mass transfer of analyte from the sample is enhanced. This system, for example, thus provided better enrichment (27-fold) than the static mode (12-fold) for two chlorobenzenes.8 When a programmable syringe pump was employed for the repetitive movement of the microsyringe plunger, the DLPME gave higher enrichment factors (60–280) than static LPME (60–180) for six polycyclic aromatic hydrocarbons (PAHs) within nearly the same extraction time (⬇20 min).9 4.2.1.3 Continuous-Flow Microextraction Another promising aspect of SME development has been directed toward achieving the continuous flow of an aqueous sample phase to a seemingly immobilized organic solvent drop, permitting the direct and continuous interaction of the drop with a fresh sample. The technique was called continuous-flow microextraction (CFME).11,12 In CFME, a polyetheretherketone (PEEK) tube is used as a holder for both the extraction solvent drop and the sample delivery supply. The drop (3 mL) is introduced into the PEEK tube via a valve and is pushed by the sample aliquot inside the tube until it reaches the tube outlet, where it remains (a little off-center of the tube) as a solvent drop. Then, the sample volume (typically 3 mL) is pumped continuously (from the PEEK tube) around the

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drop at a slow flow rate (50 mL min-1). This allows a fresh sample to interact continuously with the solvent drop; this is how the extraction proceeds. This extraction format has resulted in a highly sensitive performance with enrichment factors, for instance, between 260 and 1600 for nitroaromatic compounds and chlorobenzenes, which were detected at subfemtogram-per-milliliter levels in environmental waters.11 Few review articles have been published on microextraction procedures based on the use of a liquid-phase extractant.13,14 One drawback of drop-based microextraction procedures is drop vulnerability; this relates to its instability and potential dislodgement, which could be caused by sample complexity, a long extraction time, and a fast stirring speed. As a result, precision will often suffer significantly. 4.2.1.4 Dispersive Liquid–Liquid Microextraction Quite recently, a new concept of analyte extraction has been introduced. The principle of this procedure relies on the formation of a ternary-component liquid-phase system consisting of a dispersed extraction solvent, a dispersive solvent, and the aqueous sample. The dispersive solvent (acetone, acetonitrile, or methanol) has to be miscible with both the extraction solvent (carbon disulfide, chlorobenzene, or carbon tetrachloride) and the aqueous sample. Another important feature of this procedure is that the density of the extraction solvent must be higher than that of the aqueous sample. In addition, analyte partitioning to the extraction solvent should be high enough to achieve high analyte enrichment and recovery. In practice, a few microliters of an extraction solvent are mixed with an appropriate amount of a dispersive solvent, and the mixture is introduced rapidly to a small sample volume (5 mL) in a test tube with a conical bottom. This causes finely dispersed extraction solvent droplets to be formed, which typically results in an immensely large contact surface area between the analyte molecules and the microdroplets of the extraction solvent.15 After a predetermined extraction time, the mixture is centrifuged, which causes the extraction solvent to fall to the bottom of the test tube. This results in a rapid extraction, on a time scale of seconds to a couple of minutes; indeed, such extraction is considered time-independent, which is one of its most important characteristics. Apart from its rapidity, the technique is easy to apply, with minimal consumption of organic solvents and very high enrichment and recovery of analyte. Dispersive liquid–liquid microextraction (DLLME) has been employed for the extraction of different classes of organic pollutants16-18 as well as metal ions19,20 in relatively clean surface water samples. A potential limitation of DLLME, however, is that the procedure cannot be used for the extraction of complex samples, such as leachate or wastewater samples.

4.2.2

MINIATURIZED SPE TECHNIQUES

Further miniaturization of the SPE technique permits a reduction in the amount of organic solvent used, on-line coupling to analytical instruments, fast analysis times and excellent sensitivity. Downsizing of SPE has been focused mainly on the use of fibers, beads, and adsorbents as extraction phases that are reproducibly packed in tubes, capillaries, syringes, needles, and even micropipette tips. 4.2.2.1 Fiber-in-Tube SPE In 2002, Jinno and coworkers developed a fiber-in-tube SPE (FIT-SPE) configuration in which polymeric fibers packed in a piece of PEEK tubing a few centimeters long were utilized. The tubing was then inserted between a sample valve, connected to the sample and desorption solvent syringe pumps, and a liquid chromatography (LC) injection valve for on-line SPE and micro-LC analysis. A much smaller, grain-of-rice size PEEK extraction tube (0.5 cm) was also incorporated in the sample rotor of a microinjector valve for on-line SPE and LC analysis.21 In FIT-SPE, the sample is pumped by the sample pump through the extraction tube at a slow flow rate (8–32 mL min-1). The desorption solvent (for instance, methanol) is also delivered by the solvent pump after the positions of the switching and injection valves have been changed.

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The technique was further improved by employing a polymer coating on the polymeric fibers packed in a fused silica capillary. The coating material was based on GC stationary phases. The polymer-coated fiber-packed capillary was used as the sample loop of the LC injection valve for the extraction of phthalate esters from river water and wastewater.22 The coated-fiber extraction capillaries demonstrated a better extraction efficiency and lower limit of quantification (LOQ) than the uncoated-fiber capillaries. Also, the coated fibers were similarly packed in a PEEK tube, which was used as the injection loop or integrated in the rotor of an LC injection valve employed for the extraction of phthalates. The results clearly showed that an extraction with high selectivity could be established with an appropriate type of polymer coating.23 Compared with conventional particle-packed SPE cartridges, FIT-SPE provides an increased surface area for the extraction medium and a reduced pressure drop during extraction and desorption. Also, the undesirable plugging effect from insoluble materials in real samples can be very much diminished. Utilization of FIT-SPE has been discussed in a few review articles concerning the on-line coupling of miniaturized SPE to microcolumn liquid-phase separation techniques.24,25 4.2.2.2 Microextraction in a Packed Syringe Microextraction in a packed syringe (MEPS) is a new technique of miniaturized SPE that is fully automated and can be connected on-line to high-performance liquid chromatography (HPLC) or GC without any modifications. This technique involves a minute quantity (1 mg) of solid packing as adsorption material that is inserted into a gas-tight syringe barrel (200–250 mL) as a plug. Usually, a small volume (10–1000 mL) of sample is withdrawn into and expelled from the syringe several times by an autosampler. After the sample has passed through the solid sorbent, the solid phase is washed with water and the analytes desorbed by an organic solvent, such as methanol or HPLC mobile phase (20–50 mL), directly into the instrument injector. MEPS has so far been applied mainly to the analysis of drugs in biological samples; only one application for the extraction of PAHs in water has been published.26 One of the major advantages of the MEPS design is that the packed syringe can be used many times over, for example, more than 400 times for water samples. Moreover, the technique permits a fast handling time in the analysis of PAHs in water, the speed enhancement being 15 and 100 times compared to the literature procedures of solid-phase microextraction (SPME) and stir bar sorptive extraction (SBSE), respectively; see Sections 4.2.3 and 4.2.4. 4.2.2.3 Inside-Needle SPE The research on extraction in packed needles promptly fostered the development of a technique called in-tube extraction (ITEX). The automated ITEX device, utilized for GC analysis and developed by CTC Analytics AG (Zwingen, Switzerland), is based on an adsorbent-packed needle attached to a syringe-like robotic autosampler. Another automated device based on inside-needle SPE was designed and has been marketed commercially by Chromtech (Idstein, Germany) as “solidphase dynamic extraction (SPDE).”27 In SPDE, 7 or 50 mL of PDMS is coated on the inner surface of a few-centimeters-long needle. The coated needle is attached to a 2.5-mL gas-tight syringe and the whole setup utilized for direct immersion or headspace sampling. The sample is aspirated into and dispensed from the needle as many times as needed, depending on whether single or multiple SPDE is required. Afterwards, the solutes are thermally desorbed into GC. It is important to bear in mind that, as liquid PDMS is used in SPDE, the extraction mechanism here differs from the SPE mechanism and relates more to SPME and SBSE, as discussed in Sections 4.2.3 and 4.2.4.

4.2.3

SOLID-PHASE MICROEXTRACTION

SPME was developed by Arthur and Pawliszyn in 1990 as a viable alternative to LLE and SPE techniques that are labor-intensive and solvent demanding, although SPE requires significantly smaller quantities of solvents than LLE. The SPME device, commercially marketed by Supelco,

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consists of a fused silica fiber that is coated with a thin layer of liquid (usually PDMS) or solid polymeric material constituting the extraction phase. The coated fiber is incorporated into a syringe-like design, facilitating and integrating direct sampling, extraction, enrichment, cleanup, and analyte introduction into the analytical instrument in one step and one device. A discussion of SPME theory is beyond the scope of this chapter; the principles have been amply covered elsewhere.28 During the last 20 years or so, the SPME technique has probably reached the culmination of its development in terms of mode of operation, automation, miniaturization and interfacing to other instruments, innovation of new coating materials, calibration procedures, and fields of application. As a result of these developments, SPME has become the currently most commonly used microextraction technique in field and laboratory experiments of a multidisciplinary nature.29 Accordingly, the following sections will merely record progress in SPME from different perspectives. 4.2.3.1 Calibration in SPME One of the important aspects of any analytical method is its calibration and, therefore, much effort has been put into SPME calibration. As it is not always practicable to employ traditional calibration methods (external standards, internal standards, and standard addition) owing to the sometimes significant matrix effects in complex samples, equilibrium calibration has been suggested as an alternative. In SPME, however, it would normally take rather a long time to achieve equilibrium calibration. If sensitivity were not a concern in an analysis, reduction of extraction time would be desirable, that is, the extraction could be stopped before equilibrium; but this would thus demand a new approach to calibration. In this regard, as a way of circumventing matrix effects in environmental analysis, several diffusion-based calibration methods have been recently developed for quantification in SPME.30 One of these methods is called kinetic calibration, in which analyte absorption from the sample to the liquid coating (PDMS) on the fiber is related to analyte desorption from the coating to the sample. The isotropy of absorption and desorption in the kinetic calibration has been described by Chen et al.31 In kinetic calibration, also called in-fiber standardization, desorption of a radiolabeled standard (preloaded on the fiber coating) into the sample is used to calibrate the extraction (absorption/adsorption in the case of a liquid/solid coating) of analyte from the sample into the fiber. This calibration approach considerably facilitates the use of SPME for the on-site field sampling of water, where the control of flow velocity or addition of a standard to the matrix is very difficult. The new in-fiber standardization method has been applied for time-weighted average sampling of PAHs in Hamilton Harbor, Canada,32 and the sampling of carbofuran and carbaryl in river water.33 Calibration in SPME was the topic of two recent review papers dedicated to environmental analysis and passive sampling.30,34 It was explicitly shown in these publications that complex matrices did not have any effect on SPME performance when the new in-fiber calibration approach was implemented. Although this type of calibration circumvents matrix effects in many applications, it is anticipated that matrices having different concentrations of interfering substances could still have an influence on SPME performance, because competitive equilibria of labile concentrations of interferences with the fiber coating would not be negligible. 4.2.3.2 Recent Trends in SPME Applications As the technique inherently works under equilibrium conditions and the amount of analyte extracted is negligible (<10%), SPME as a passive sampling method has found applications in different disciplines in general and in environmental analysis in particular, such as estimating free bioavailable chemical concentrations and distribution constants.35 SPME has, for instance, been used to measure free, rather than total, pollutant concentrations in environmental compartments. These free concentrations in aquatic environments are of the utmost importance, as it is believed that free pollutant fractions are bioavailable, causing toxicity36,37 and bioaccumulation38 in aquatic organisms. SPME fibers have also been employed as biomimetic sampling devices to predict the toxicity of a chemical

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75

from its chemical uptake and bioavailability.39,40 Moreover, SPME can be implemented as a tool for understanding the sorption and distribution of a pollutant in environmental multicompartments such as humic substances and other binding phases), which can be vitally important for environmental science and ecotoxicological studies.41,42

4.2.4

STIR BAR SORPTIVE EXTRACTION

The conventional polymeric coating, PDMS, employed in SPME has a film thickness of 100 mm, which corresponds to a volume of about 0.5 mL for the whole fiber. In SPME, the thin PDMS film provides the highest enrichment when equilibrium between the film and sample is realized, the attainment of which depends largely on analyte hydrophobicity and distribution to the coating. With thin PDMS films, SPME does not generally afford quantitative exhaustive extraction, which renders SPME a less sensitive technique even for nonpolar compounds and an unsatisfactory sampling device that fails to extract polar analytes. Implementing SPME for total exhaustive extraction is conceivably plausible if the PDMS film thickness is increased dramatically. 4.2.4.1 SBSE Development Accordingly, Baltussen et al.43 fabricated a magnetic rod housed in a short piece of glass tubing, which can be envisioned as a small stir bar. The stir bar was coated with PDMS (55 or 219 mL), and then used for stirring (sampling) water samples (10–250 mL) containing volatile and semivolatile compounds. The technique, named “SBSE,” in principle works like SPME and depends mainly on the analyte partition coefficient between n-octanol and water (Ko/w), but also on the sample/PDMS volume ratio. After SBSE sampling is complete, the stir bar is placed in a thermal desorption unit (TDU) for analyte desorption. The TDU equipment (commercially available from Gerstel GmbH, Mülheim an der Ruhr, Germany) is fully automated and connected on-line to a GC equipped with a programmable temperature vaporizer (PTV) injector for simultaneous cryotrapping of the analytes before injection. Another approach for analyte desorption is to place the stir bar in a small volume of a conventional HPLC liquid (or mobile phase) for HPLC analysis. The SBSE stir bars are trademarked as TwistersTM; they can also be purchased from Gerstel. For more detailed information on SBSE technology, the reader is referred to two recent review articles.44,45 Comparing SPME with SBSE, the latter embodies a magnetic stir bar inserted into a glass jacket that is coated with a much thicker PDMS coating (100–400 times more PDMS). Accordingly, a much better sensitivity for nonpolar and polar compounds is achievable and exhaustive quantitative recovery is more readily attainable in SBSE than in SPME. The SBSE technique has been developed extensively since its introduction in 1999, the focus in this respect being mainly on its mode of operation and applications; several attempts have been made at improving material coatings. 4.2.4.2 SBSE Modes of Operation The mode of operation in SBSE resembles that in SPME but with a few distinctive differences. For instance, after carrying out an SBSE procedure, two Twisters (dual SBSE extraction) can be simultaneously desorbed in one thermal desorption tube in order to further enhance the sensitivity. In the so-called multishot mode, up to five Twisters were desorbed in one desorption tube with in situ derivatization for quantification of estrogens in river water.46

4.3 ANALYTICAL TECHNIQUES BASED ON NONPOROUS POLYMERIC MEMBRANES The types of polymeric membranes that have attracted much interest for analytical applications and are nowadays in common use are characterized as nonporous membranes such as low-density polyethylene (LDPE), dense PP and PDMS silicone rubbers, and asymmetric composite membranes

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such as silicone/polycarbonate and silicone/porous polypropylene (PP) membranes. The nonporous polymeric membranes (flat sheet (FS) or hollow fiber (HF)), especially dense silicone rubbers, are employed for analyte extraction and preconcentration in several different configurations. The nonporous polymeric membrane can be used to separate two different or similar phases, which can be 1. 2. 3. 4.

An aqueous phase and a gaseous or vacuum phase Two gaseous phases An aqueous phase and an organic phase Two aqueous phases.

The most important characteristic of nonporous membranes is that they are hydrophobic and contain no pores in the polymeric structure. This means that these membranes not only selectively act as a barrier to particles and polar species, but they also provide unique selectivity and specificity for the permeation and transport of a specific group of compounds that can readily solubilize and diffuse in the membrane material. The analyte extraction rate (permeability) in a nonporous membrane separation process is governed by the “solution–diffusion” mechanism, as commented on earlier. The analytical extraction systems related to points 1 and 2 are pervaporation-based techniques (such as those mentioned in Sections 4.3.1 and 4.3.2). Extraction based on the membrane separation of an aqueous phase and an organic phase (point 3 above) will be dealt with in Section 4.3.3. As the system concerning point 4 is very rarely used, it will not be considered here.

4.3.1

MEMBRANE INLET (INTRODUCTION) MASS SPECTROMETRY

Nonporous polymeric membranes have been incorporated as sample inlets in mass spectrometry (MS) for the direct sampling of volatile and semivolatile organic compounds (VOCs and SVOCs). The technique of membrane inlet (introduction) mass spectrometry (MIMS) has achieved tremendous success in the last two decades in terms of instrumentation and applications. Figure 4.1 depicts the experimental setup of (i) in-sample membrane MIMS and (ii) direct insertion (near the ion source in MS) membrane MIMS. The core development of MIMS has centered upon MS ionization techniques for the analysis of aromatic contaminants in water,47 improving membrane extraction selectivity48 and enhancing MIMS sensitivity by cooling and heating the membrane (trap and release MIMS).49,50 A dedicated review has been written on the applications of MIMS in environmental analysis.51

4.3.2

MEMBRANE EXTRACTION WITH SORBENT INTERFACE

The use of silicone membranes as an interface in MIMS for direct extraction and analysis by MS has fostered their implementation for extraction purposes that can be combined off-line or on-line with other analytical instrumentation, such as GC. The technique of membrane extraction with sorbent interface (MESI) (Figure 4.2) employs the pervaporation principle in a nonporous polymeric membrane unit, where the membrane is used as a selective barrier for the extraction of VOCs and SVOCs in gaseous or liquid samples. In MESI, the sample flows on one side of an FS or HF membrane and the analytes diffuse through the membrane to the other side, where a continuous flow of a carrier gas is applied. The analytes carried by the stripping gas are focused prior to GC injection via a sorbent interface consisting of a trap and a heating coil. MESI with a cap sampling device has been applied for the continuous monitoring of VOCs in surface waters.52 MESI has subsequently been improved in terms of technical developments, instrument configurations, and applications for on-site sampling of water.53,54

Modern Techniques of Analyte Extraction

FIGURE 4.1 ion source.

77

(a) MIMS systems with direct membrane sampling and (b) direct insertion probe in MS

MESI operation requires processing of the whole sample to be extracted and has to reach steadystate permeation, which usually takes a long time. Thus, a new technical modification of MESI, called pulse introduction (flow injection-type) membrane extraction (PIME), has been developed, in which the sample is introduced to the membrane as a pulse pushed by a stream of eluent (usually water).55 This means that attaining a steady state is no longer crucial. PIME therefore provides not only a faster response and higher sensitivity, but also allows extraction of individual samples via discrete injections in addition to continuous on-line monitoring by sequential injection of a series of samples. Guo et al.56 described a mathematical model for the PIME permeation process, which showed that (a) there was a trade-off between the sensitivity and the time lag (the time taken to complete the permeation process) and (b) a large sample volume and a low flow rate enhance the sensitivity but also increase the time lag. It is important to remember that, as in all types of MESI designs, the time necessary to complete analyte permeation through the membrane can be fairly long, because the positive pressure of the stripping (carrier) gas on the acceptor side of the membrane slows down the permeation. The aqueous boundary layer formed on the membrane is believed to be the major contributor to mass transfer resistance. To increase extraction efficiency and speed up analysis (a shorter time lag), a stream of nitrogen gas can be introduced into the membrane prior to extraction and after sample elution. This will reduce, if not eliminate, the static aqueous boundary layer on either side of the membrane.57 It was also found that using a gas as sample carrier (gas injection membrane extraction) instead of a water stream (as described previously) caused minimal axial mixing of the sample, which eliminated tailing in the permeation profiles, and significantly reduced the boundary layer (i.e., faster extraction—a shorter time lag) with no loss in sensitivity. Moreover, this approach required simpler instrumentation and operational procedures.58

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(a)

Sorbent interface

Sample

Carrier gas out to GC GC

Carrier gas in

Hollow fiber membrane

Sorbent trap Heating coil

Metal support

(b)

Flat membrane module

Nonporous membrane Metal support

Carrier gas in

Carrier gas out to GC

Sorbent interface

GC

Sample

Sorbent trap

Heating coil

FIGURE 4.2 Two on-line MESI-GC setups with (a) HF and (b) FS membrane modules.

4.3.3

MEMBRANE-ASSISTED SOLVENT EXTRACTION

Another use of nonporous membranes in extraction sheds light on the exploitation of a membrane as a phase separator between an aqueous phase and an organic phase, thus forming a three-phase system with an aqueous–polymeric–organic configuration. Hauser et al. designed an experimental setup for the aqueous–polymeric–organic format carried out in a glass extraction cell. The new technique was called membrane-assisted solvent extraction (MASE). The extraction cell consisted of two compartments separated by a nonporous FS membrane of LDPE. One of the compartments was small, accommodating about 800 mL organic extractant, and the other was relatively large, housing a 10-mL sample of heavily chlorobenzene-contaminated groundwater.59 After extraction, the large volume injection (LVI) of the extract into the GC was deemed necessary to enhance sensitivity. A modified extraction cell containing a bag-shaped membrane made of LDPE, instead of an FS membrane, was designed to contain the extraction solvent for the extraction of polycyclic musk compounds and pharmaceuticals in wastewater.60 The extraction cell was further developed in terms of membrane design and material. A dense nonporous PP membrane was preferably chosen as a membrane bag in the extraction cell, which was incorporated into a fully automated MASI device that is now commercially available from Gerstel (Mülheim an der Ruhr, Germany).

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79

This device has been applied for the extraction of different classes of organic species in wastewater.61

4.4 ANALYTICAL TECHNIQUES BASED ON THE USE OF LIQUID MEMBRANES 4.4.1 SUPPORTED LIQUID MEMBRANE (SLM) EXTRACTION 4.4.1.1 SLM Extraction Principle The first realization and application of SLM in analytical sample preparation was initiated by Audunsson62 in 1986. The SLM extraction procedure involves partitioning uncharged (but ionizable) analytes from an aqueous sample phase (donor) to an immiscible organic liquid phase immobilized in a thin porous FS or HF polymeric membrane made of PP or PTFE (thus making the membrane nonporous). The analyte is then backextracted from the organic phase into another aqueous phase (acceptor) on the other side of the membrane. The ionizable analytes have to be in an extractable form in the aqueous sample before extraction so that they can dissolve in the organic phase. It has been discussed in Sections 4.2.3 and 4.2.4 that SPME and SBSE systems do not provide satisfactory extraction of polar species because the PDMS coating material used is hydrophobic and thus best suited for extracting nonpolar analytes (log Ko/w > 4). SLM extraction is considered superior for the extraction of polar species (2 < log Ko/w < 4). The analyte in the sample can be neutralized by adjusting the sample pH, or by adding an ion pairing or complexing agent in the sample or in the membrane liquid if the analytes happen to be permanently charged. Hence, the analytes in the sample diffuse through the membrane liquid, and, on the membrane/acceptor interface, are instantaneously trapped on the acceptor side by chemical means. Analytes can be trapped in the acceptor solution if the sample pH is changed or an agent added that can selectively capture the analytes and make them nonextractable, preventing redissolution in the membrane liquid. The performance of SLM extraction is characterized by two measures: the enrichment factor (Ee) and the extraction efficiency (E). E measures how much of the analyte in the sample is recovered on the acceptor side after extraction: E = (CA /CS) × (VA /VS), and Ee reflects how many times the concentration in the acceptor is increased compared to the initial sample concentration: Ee = (CA /CS). CA and CS are the final acceptor and initial sample concentrations, respectively. Similarly, VA and VS are the acceptor and sample volumes, respectively. A more comprehensive elaboration of SLM principles63 and mass transfer kinetics,62,64 as well as the role of the octanol–water partition coefficient in SLM extraction of ionizable compounds,65 is given elsewhere. 4.4.1.2 SLM Unit and System Configurations The heart of the SLM extraction procedure is the SLM unit, in which analyte extraction, preconcentration, and sample cleanup take place in one single step. The design of the SLM unit can be engineered according to the intended use of the unit. For instance, if an SLM unit is needed for an automated and flowing sample extraction, it can be manufactured from two blocks of polytetrafluoroethylene (PTFE), polyvinylidine difluoride (PVDF), or titanium. However, for nonautomated, nonflowing SLM extraction, a short piece of porous HF membrane is used. Three physical realizations of SLM modules have been reported: they are based on spiral, flat, and HF extraction units, as presented in Figure 4.3. Where a porous FS membrane is the liquid support in an automated flowing SLM configuration, flat and spiral modules are usually used, in which, respectively, a straight and a spiral machined groove is made in the inner two surfaces of the unit blocks.66,67 When the membrane support is sandwiched between the two unit blocks, donor and acceptor channels are formed on either side of the membrane.

80

Analytical Measurements in Aquatic Environments (a)

(b)

Donor side Membrane Acceptor side

(c)

(d)

Sample Sample inlet outlet

Organic membrane Donor side Membrane Acceptor solution Acceptor side Extraction unit – N A N Solvent Solvent BH+ HA inlet outlet

FIGURE 4.3 SLM extraction units with (a) spiral groove of 1 mL channel volume, (b) straight groove of 10 mL channel, (c) miniaturized straight groove of 1.65 mL channel volume, and (d) an HF membrane exemplifying an SLM extraction of an acidic analyte in an acidic sample containing the analyte (A), basic compounds (B), and neutral species (N).

Miniaturized and on-line flowing FS-SLM systems with 1.65 and 10 mL channel volumes have been applied, for example, for the extraction of simazine in mineral water68 and haloacetic acids in water.69 But not only do these flowing SLM systems yield low E values, they are usually prone to tubing blockage and analyte carryover. To circumvent these problems in FS-SLM, the HF-SLM configuration in the form of a nonautomated, nonflowing, off-line setup has been shown to be a better alternative, which has been investigated with regard to the extraction of dinitrophenols and chlorophenols in river and leachate water.70,71 One way of accomplishing this operational mode of HF-SLM was to seal one end of a short piece of HF (⬇4 cm long) and fill the acceptor phase in the HF lumen through the other, open end. The HF was then immersed in an organic liquid to impregnate its pores, after which the HF device was added to the stirred sample for sampling. An HPLC syringe was used for filling the acceptor phase, supporting the HF during extraction, and emptying the HF lumen after extraction, as shown in Figure 4.4.70 Owing to the high surface area-to-volume ratio of the HF (immersed in a stirred sample) and its oneoff use, the HF-SLM procedure resulted in high E values with no carryover problems.

Metallic stand HPLC syringe

HF Magnetic stir bar

FIGURE 4.4

Magnetic stirring device

A nonautomated, nonflowing, off-line HF-SLM extraction setup.

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Another format of the HF-SLM procedure was to employ a 15–20 cm long piece of HF as the extraction device. The HF lumen was then filled with acceptor solution using a microsyringe, and a loop made out of the HF. This loop was then soaked in an organic liquid before being added to the sample agitated on a shaker.71 There are several review papers on SLM extraction that touch upon off-line or on-line SLM hyphenation to analytical instruments as well as the fields of SLM applications.67,72 The following discussion will focus mainly on other aspects of SLM, such as transport mechanisms, selectivity, and equilibrium sampling with SLM. 4.4.1.3 Transport Mechanisms in SLM In SLM extraction, the transport mechanism is influenced primarily by the chemical characteristics of the analytes to be extracted and the organic liquid in the membrane into which the analytes will interact and diffuse. Analyte solubility in the membrane and its partition coefficient will have the main impact on separation and enrichment. Analyte transport in SLM extraction can be substantially categorized into two major types: one is diffusive transport (or simple permeation) and the other covers facilitated transport (or carrier-mediated transport).73 4.4.1.3.1 Diffusive Transport Diffusive transport across an SLM membrane can be conceived of as five steps of analyte diffusion in a single phase and partitioning in two different phases: the analyte (a) diffuses in the bulk aqueous sample through the aqueous boundary layer to the sample/membrane interface; (b) partitions between the aqueous sample and the organic phase in the membrane in accordance with the partition coefficient, often approximated by the Ko/w value of the analyte; (c) diffuses through the organic membrane phase along a concentration gradient until it approaches the membrane/acceptor interface; (d) partitions between the organic phase and the acceptor phase, where it is trapped; and (e) diffuses through the aqueous boundary layer to the bulk acceptor phase. Figure 4.5 shows an example of the diffusive transport of an ionizable basic analyte being exhaustively extracted from an alkaline sample solution through an organic phase impregnated in the pores of an HF (dipped in the sample) into an acidic acceptor solution filling the HF lumen. The uncharged basic analyte (B) is selectively extracted into the organic liquid and, on the acceptor side, the acidic solution (pH = 3.3 units less than the analyte pKa value) irreversibly and chemically traps the analyte from the organic phase in a charged form (BH+). On the other hand, acidic compounds (A-) in the sample will already be charged and will thus not be enriched. Moreover, the neutral species (N) could be extracted, but not enriched, and the size and charge of macromolecules (if they are ionizable) will prevent them from entering the membrane. But even if some macromolecules do enter the liquid membrane, their low diffusion coefficients will cause a slow rate of transport. Accordingly, enrichment of small basic compounds and

Basified sample pH > pKa + 2

Hollow fiber wall

Organic solvent

B

BH+

A– N

Concentration gradient

N pH < pKa – 3.3

Acidic acceptor

FIGURE 4.5 Schematic representation of selective SLM extraction of a small basic compound (B).

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sample cleanup will be efficient. In a very similar manner, small ionizable acidic analytes can be extracted by reversing the pH in the sample and acceptor phases.66 4.4.1.3.2 Facilitated Transport The other type of transport, facilitated transport, involves an analyte-specific carrier mixed in the organic membrane phase at a certain concentration. The solubility of the carrier in the surrounding aqueous phases has to be very low to prevent leakage, which would prevent specific analyte transport across the membrane. As an example of carrier-mediated transport, Figure 4.6 (left) illustrates the coupled countertransport of an anionic analyte—aminomethyl phosphonic acid (AMPA) (a metabolite of the herbicide N-phosphonomethyl glycine (glyphosate))—in the sample and a cationic carrier—methyltrioctylammonium chloride (known as Aliquat 336)—in the membrane liquid.74 This kind of transport basically involves the formation of an ion pair between the cationic carrier in the membrane and the anionic analyte in the sample. The ion pair diffuses through the organic membrane until it approaches the boundary with the acceptor side. There, the ion pair breaks up so that the anionic analyte is left on the acceptor side, whereas the cationic carrier takes a chloride ion in place of the analyte anion and returns in the form of a chloride complex. On the way back, the chloride anion is released on the sample side and transport continues. The driving force for such transport is the chloride anion gradient from the acceptor to the sample, which means that transport will ultimately cease when the chloride gradient no longer exists. Anionic carriers in the membrane, such as di-2-ethylhexyl phosphoric acid (D2EHPA), have also been investigated for the coupled countertransport of cationic analytes such as metal ions from the sample side to the acceptor side. The driving force for this transport is, however, a proton gradient from the acceptor to the sample (Figure 4.6, right). This figure depicts schematically the transport of cationic metal ions from the sample to the acceptor side and the countertransport of a proton (pH gradient) in the opposite direction. Such a transport mode has been used, for example, to enrich permanently positively charged species, such as metal ions,75 and bipyridilium herbicides (diquat and paraquat)76 in river water.

FIGURE 4.6 Illustration of the SLM-coupled countertransport of an anionic herbicide (glyphosate) metabolite, AMPA- (left) and a cationic metal ion, M+ (right).

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83

4.4.1.4 Selectivity in SLM The discussion in Section 4.4.1.3 on transport mechanisms in SLM has manifestly demonstrated another facet of tuning analyte-selective extraction. For example, Figure 4.5 clearly demonstrates the selective extraction of a basic compound—all that is required here is a simple adjustment of the pH on either side of the membrane. Also, Figure 4.6 neatly illustrates the possibility of performing such selective extraction of anionic and cationic species in another transport mechanism that employs selective carriers. Thus, by fine-tuning the chemistry/composition of the sample, membrane liquid, and acceptor phases, analyte-selective extraction can be tailor-made. The intention in this section is to further demonstrate SLM selectivity by highlighting a few worthwhile examples of tuning selectivity in the acceptor phase. SLM selectivity can be tuned in the acceptor phase in several ways, such as using a selective complexing agent that readily undergoes a chemical reaction with the analyte on the acceptor side (e.g., Cu2+ and a complexing ligand).77,78 Another means of achieving selective trapping in the acceptor is to suitably incorporate an analyte-specific antibody that will interact selectively with the analyte (antigen), forming an antigen– antibody complex that does not affect the analyte concentration gradient over the membrane.79 This immuno-SLM (ISLM) system can be run in an on-line flowing configuration that integrates sampling, extraction, and detection by a suitable format of immunoassay methods. An FS-SLM unit with a channel volume of 10 mL has been typically used in ISLM for accommodating a free acceptor-dissolved antibody.79-82 In order to achieve markedly high sensitivity and to minimize consumption of an expensive antibody, a miniaturized mSLM unit with a channel volume of 1.65 mL was implemented.68 The acceptor channel in the mSLM unit was gold-coated, and the antibody was covalently bound to the gold surface via a self-assembled monolayer of sulfur-containing material. With this design, an LOD of 0.1 ng L -1 of simazine was obtained in mineral water. A novel design of an ultrasensitive ISLM system with minimal consumption of antibody has been constructed on the basis of antibody immobilization on magnetic beads in a 10-mL acceptor channel. The position of the antibody molecules in the acceptor phase was meticulously controlled by two alternating and opposing magnetic fields generated by a current applied to either of two electromagnets placed above and below the acceptor channel of the SLM unit.82 In this configuration, Tudorache et al. succinctly described the superior sensitivity obtained by the mobilized (forced movement up and down in the acceptor) over the immobilized antibody molecules, permitting a 2000 times concentration enrichment for simazine with an LOD of 13 pg L-1. Immunological trapping in ISLM has been used to quantify 4-nitrophenol in wastewater,79 atrazine80 and 2,4,6-trichlorophenol81 in river water, and simazine in mineral and river water samples.68,82 4.4.1.5 Equilibrium Sampling Through SLM As mentioned in Section 4.2.3.2, nonexhaustive SPME at equilibrium can be used for speciation studies and the sampling of freely dissolved nonpolar compounds. However, speciation and sampling of polar compounds in aqueous samples is extremely difficult with SPME. As an alternative, the appropriateness of SLM extraction of polar species makes the SLM technique uniquely suitable for performing speciation studies of such compounds, when SLM operation is carried out at equilibrium and under nonexhaustive conditions. This SLM extraction mode, based on establishing an equilibrium between the undisturbed sample phase (to maintain natural equilibria) and the acceptor buffer phase, and working at nondepletive conditions (E < 5%), has been termed “equilibrium sampling through membranes” (ESTM). Equilibrium sampling devices (ESDs) operating at negligible depletion of the sample, such as ESTM, will require a large volume ratio of sample to extractant (the acceptor solution in ESTM) if analyte depletion is excessive at small ratios.35 ESDs are essentially beneficial for sensing free analyte fractions involved in secondary equilibria. These fractions are believed to be bioavailable for uptake by organisms in environmental compartments, thus causing toxicity.

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The operational performance of an HF-based ESTM technique was first described by Liu et al.71 A 15-cm piece of HF was filled with an acceptor buffer solution, after which the HF was made into a loop. This loop-like HF device was soaked in n-undecane, and then immersed in 1 L of a river or leachate water sample for extraction of freely dissolved chlorophenols. This HF-loop device was also employed for selective ESTM sampling of freely available Cu +2 in leachate water.78 The selectivity stemmed from a selective liquid membrane (di-n-dihexyl ether) containing a carrier (crown ether/oleic acid) and a selective stripping agent in the acceptor solution.

4.4.2 MICROPOROUS MEMBRANE LIQUID –LIQUID EXTRACTION 4.4.2.1 MMLLE Principle Microporous membrane liquid–liquid extraction (MMLLE) is a two-phase extraction setup. In MMLLE procedures, the membrane material and format (FS and HF), extraction units, and system configurations are identical to those described in SLM (Section 4.4.1.2).63 The two-phase HF-MMLLE system is identical to that used in Section 4.4.3, although sometimes with minor differences. In contrast to three-phase SLM extraction, MMLLE employs a microporous membrane as a miniaturized barrier between two different phases (aqueous and organic). One of the phases is organic, filling both the membrane pores (thus making the membrane nonporous) and the compartment on one side of the membrane (acceptor side). The other phase is the aqueous sample on the other side of the membrane (donor side). In this way, the two-phase MMLLE system is highly suited to the extraction of hydrophobic compounds (log Ko/w > 4) and can thus be considered a technique complimentary to SLM in which polar analytes (2 < log Ko/w < 4) can be extracted. 4.4.2.2 Miniaturization, Automation, and Hyphenation of MMLLE As in the SLM systems, FS- and HF-MMLLE configurations can be run automatically in flowing modes and operated off-line or connected on-line to analytical instruments. Recently, a microfluidic chip-based FS-MMLLE system was reported.83 In addition, miniaturized, nonautomated, nonflowing, off-line MMLLE systems are usually used with HF membranes. The emphasis in this section will be placed on these latter modes of MMLLE operation. 4.4.2.2.1 Automated, Flowing MMLLE 4.4.2.2.1.1 Off-Line Systems Flowing FS- and HF-MMLLE systems are usually operated by pumping the sample solution on the sample side of the membrane, which can be done with a peristaltic or syringe pump. The stagnant or flowing organic solvent is supplied by another similar pump to the acceptor channel and membrane pores. The impact of several factors on the MMLLE extraction yield of PAHs in water has been comprehensively studied using a flowing FS-MMLLE system and off-line analysis with GC-flame ionization detection (GC-FID).84 The flowing FS-MMLLE procedure combined with off-line GC-mass spectrometry (GC-MS) analysis has been utilized for the extraction of nonionic and derivatized ionic organotin compounds in river water.85 4.4.2.2.1.2 On-Line Systems Flowing MMLLE systems have been established in different layouts with automation and on-line hyphenation to GC and HPLC analysis. An automated on-line FS-MMLLE-GC system with a loop-type interface compatible with LVI was used for the extraction of pesticides and PAHs in surface waters.86 In another study, pressurized hot water extraction (PHWE) was coupled on-line to a FS-MMLLE-GC-FID system and applied to the analysis of PAHs in soil, where MMLLE was used as a cleanup and concentration step of the PHWE extract prior to final GC analysis.87 In addition, an HF-MMLLE setup was incorporated in PHWE and GC, resulting in an online PHWE-HF-MMLLE-GC system, where the HF membrane module contained 10–100 HFs. The system served for the extraction and analysis of PAHs in soil and sediments;

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a significant improvement in extraction efficiency and low LOQs was obtained in comparison to the FS-MMLLE-based system.88 Flowing FS-MMLLE with on-line hyphenation to HPLC has also been investigated. Sandahl et al. were the first to interface FS-MMLLE with reversed-phase HPLC for the on-line extraction of methyl-thiophanate in natural water, obtaining an LOD of 0.5 mg L -1.89 Also, a parallel FS-SLM and FS-MMLLE design was coupled on-line to reverse-phase HPLC for the extraction of methylthiophanate (by MMLLE) and its metabolites (by SLM) in natural water.90 In addition, on-line coupling of FS-MMLLE and normal-phase HPLC has been successfully applied in the determination of vinclozolin (E e = 118 and LOD = 1 mg L -1) in surface water 91 and of in-sample ionpaired cationic surfactants (E e > 250 and LOD = 0.7–5 mg L -1) in river water and wastewater samples.92 4.4.2.2.2 Extracting Syringe Device As shown above, several attempts were made to establish automated flowing MMLLE systems that are interfaced on-line to an analytical instrument. The concept of the Extracting Syringe (ESy) stemmed from these earlier attempts. The ESy device automatically combines on-line microMMLLE and GC analysis in one step, as depicted in Figure 4.7. The ESy integrates automated sample pretreatment with simultaneous analyte enrichment, extract cleanup and injection, and analyte separation by GC in a closed system with minimal handling steps. The name “ESy” was given because, after extraction in the ESy has been completed, the ESy setup moves down, allowing the GC needle in the ESy to penetrate the GC septum and injector for whole extract injection. In the ESy, a miniature FS membrane is supported by two small, identical pieces of PP plastic, constituting a miniaturized membrane unit called an “ESy extraction card” (see the inset in Figure 4.7), which is housed under mechanical pressure in a card holder. The two PP pieces have dimensions of 2 mm ¥ 20 mm ¥ 40 mm. The inner surface of each piece contains a machined groove defining a microchannel of 1.65 mL volume (0.125 mm depth ¥ 0.6 mm width ¥ 22 mm length). The very small piece of FS membrane (2 mm width ¥ 22 mm length ¥ 25 mm thickness) is fastened in

Sample pipet

Extraction card Donor side

Samples tray

Membrane Acceptor side

Card guard Organic solvent

Sample waste

GC needle

Column inlet

Sample syringe pump

Washing fluid

Solvent syringe pump

mECD detector

Retention gap and GC capillary column

FIGURE 4.7

The on-line ESy-GC instrument with extraction card shown in the figure inset.

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between the two PP pieces and is thus sandwiched when the two pieces are pressed together. In this ESy system, a solvent syringe pump is connected to the acceptor side of the ESy card so as to impregnate the membrane and fill the acceptor channel with organic solvent. Afterwards, the sample (1–3 mL) is continuously delivered by a syringe pump to the sample channel on the other side of the extraction card (donor side). When extraction is complete, the card holder moves down and its needle penetrates the GC septum for direct injection of the whole extract. The FS-based ESy has been utilized in a small number of applications. For example, an ESy was coupled on-line with full automation to an on-column GC-electron capture detection (GC-ECD) system for the extraction and analysis of polychlorinated biphenyl (PCB) congeners in river water.93 1 mL samples with 40% acetonitrile containing 10 PCB congeners were automatically run and extracted at 100 mL min-1. One of the major findings in this work pertained to the importance of acetonitrile as organic modifier in the sample and washing fluid. Acetonitrile as sample modifier played a central role in enhancing PCB enrichment; this enabled repeatable extractions and prevented adsorption onto glass container walls and ESy tubing, thereby minimizing carryover problems. When the optimal acetonitrile content was used in the sample and washing procedure, the on-line ESy-GC-ECD system yielded Ee values between 33 and 41 and LOD values between 2 and 3 ng L -1 for all the PCBs studied. In another application, Esy-GC-ECD was applied to the extraction of 14 organochlorine pesticides (OCPs) in spiked and contaminated complex samples, such as raw leachate water and soil– water slurry samples.94 A downsized filtration vessel was deemed crucial for sample filtration after acidification and the addition of activated copper granules (to remove elemental sulfur) and 20% acetonitrile (to prevent adsorption and enhance enrichment). Under optimal conditions, extraction of a 3-mL leachate water sample dispensed at a flow rate of 100 mL min-1 gave Ee values between 32 and 242 and LODs between 1 and 20 ng L -1. It was also demonstrated that, since ESy extraction is dynamic and its extraction efficiency low, calculation of “relative recovery” was more relevant than “extraction efficiency” in all ESy applications. Phthalate esters in river and leachate water were also extracted with an ESy-GC-FID system. Here, owing to the large variation in the polarity of the phthalate esters, 50% methanol had to be added to the samples as organic modifier in order to extract the most nonpolar phthalate esters (di-2-ethylhexylphthalate and di-n-octylphthalate); the relatively polar phthalate esters were extracted from unmodified samples. The time required to extract a 1-mL sample was 20 min; Ee values of 54–110-fold and LODs of 0.2–10 ng mL -1 were obtained.95 4.4.2.2.3 Nonautomated, Nonflowing, Off-Line MMLLE To simplify the above-mentioned MMLLE systems and, unlike the automated flowing MMLLE, the nonautomated, nonflowing design of MMLLE is simple to prepare manually and is an easy-touse extraction procedure that is always done off-line prior to GC analysis. In this context, only a short piece of HF membrane is employed as an extraction device; after the HF lumen and pores96 or only the pores97 have been filled with an appropriate organic solvent, the membrane is immediately immersed in the aqueous sample. The principle of this two-phase HF-MMLLE system is also called HF liquid-phase microextraction (HF-LPME) and will be briefly commented on in the next section. A very simple HF-MMLLE configuration has been employed by flame-sealing the two ends of the HFs. The HFs were then soaked in n-undecane for a period of time so as to allow them to fill with solvent; this makes simple HF-MMLLE devices. In this way, a single HF was utilized for the MMLLE of eight polybrominated diphenylethers (PBDEs) in 100 mL samples of tap, river, and leachate water. The analysis was done by manual injection of 2 mL of the HF lumen content into a splitless GC injector followed by GC-MS analysis in selected ion monitoring (SIM) mode. Under optimal HF-MMLLE conditions, the extraction was exhaustive (E = 57–104%), giving very good enrichment (Ee = 2800–5200-fold), very low LOD (<1.1 ng L -1), and relative recoveries of 85–110%. Two PBDEs were detected and quantified in leachate water at concentrations of 3.5 ng L -1 for BDE 153 and 23 ng L -1 for BDE 183.96

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87

In contrast to the exhaustive HF-MMLLE system mentioned above, a second HF-MMLLE configuration explored the possibility of using nonautomated, nonflowing, off-line HF-MMLLE for equilibrium sampling and nonexhaustive depletion of an analyte in environmental aqueous samples. To do this, the organic solvent was immobilized in the pores of a 1-cm HF membrane. This was made possible by using an HPLC syringe plunger inserted completely into the lumen of the 1-cm-long HF; after this, only the HF pores were impregnated in 2-heptanone (⬇3.3 mL). This arrangement allowed the HF lumen volume to be fully occupied by the plunger, so no solvent was filled into it. It could be argued that this format is not a membrane extraction technique, but it is useful nonetheless. The HF-in-plunger device was dipped in 500 mL river or aqueous sewage samples. With this large volume ratio between sample volume and organic solvent volume, nondepletive extraction conditions were established. Under equilibrium and no-depletion (E = 2.5%) conditions, this experimental setup was employed for quantifying the free concentration of an ibuprofen degradation product in sewage water samples. Neither filtration nor sample pretreatment was needed, although there was a significant sewage water matrix effect. This type of HF-MMLLE design gave E e values of over 2000 in the fiber pores and of over 300 after dilution, and LOD values of 7 ng L -1 in river water (downstream of the sewage treatment plant) and 14 ng L -1 in sewage water, where analyte concentrations of 26 and 40 ng L -1 were quantified.97

4.4.3 TWO-PHASE HF-LPME The chemical principle of two-phase HF-LPME is identical to that in the FS- and HF-MMLLE systems discussed in the previous section. Thus, it is merely a case of different names for similar technical approaches. The intention of this section is to give a brief synopsis describing the most recent and important developments in this technique, and its potential automation. 4.4.3.1 Development of Two-Phase HF-LPME The first setup of a two-phase HF-LPME procedure was established by Lee’s group at the University of Singapore. A conventional GC-microsyringe needle fixed into one end of a 1.3-cm HF was used and the setup was employed for the extraction of triazine herbicides in water and soil–water slurry samples.98 The GC syringe was utilized for supporting the HF, filling and collecting the organic solvent (3 mL) from inside the HF, and finally, for direct manual injection of the solvent into a GC system. The new procedure gave Ee > 140 (3–5 times higher than static-single drop LPME) for several triazines with LOD between 7 and 63 ng L -1 in water samples and 40 and 180 ng L -1 in soil–water slurry samples. A few technical modifications have been introduced to the HF-LPME technique. Jiang et al.,99 for example, extended the microsyringe-based HF-LPME to solvent bar microextraction (SBME), which exemplifies a more miniaturized version of the system described in the “nonautomated, nonflowing HF-MMLLE” section. In the SBME procedure, the organic solvent was confined within a short piece of an HF membrane (1.5 cm) sealed at both ends, thus no syringe was used. This extraction with organic solvent (1.5–4 mL) in a porous microbag of PP HF involved tumbling the solvent bag in a soil-slurry sample by using a stir bar, which resulted in faster mass transfer and higher enrichment factors for chlorobenzenes compared with syringe-based static HF-LPME. In another technical development of HF-LPME, Wang et al.100 introduced a fiber-in-tube LPME device, where several PTFE HF membranes (14–28 HFs) packed into a short piece of PTFE tube (1–2 cm) were impregnated with an organic extraction solvent. After HF impregnation, the tip of a GC microsyringe was fitted into the packed tube and the whole set was immersed in a river water or wastewater sample for extraction of substituted benzenes. In another study, done by Lee et al.,101 simultaneous in-fiber derivatization and HF-LPME of degradation products of chemical warfare agents in water was reported. This work adapted a 1:1 mixture of chloroform as extraction solvent and N-(tertbutyldimethylsilyl)-N-methyltrifluoroacetamide as derivatizing agent in the HF lumen. After extraction, 1 mL of this mixture was injected into GC-MS for analysis.

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4.4.3.2 Automation of Two-Phase HF-LPME The HF-LPME technique is seemingly difficult to automate. The first attempt at automating this technique was reported by Zhao et al., who developed a semiautomated dynamic two-phase HF-LPME procedure for the extraction of fluoranthene and pyrene in aqueous samples.102 In this procedure, the organic solvent (3 mL) inside the HF (1.5 cm) was repeatedly withdrawn from and discharged into the HF (5 s waiting time after each withdrawing–discharging cycle) by a conventional GC syringe that was mounted onto a programmable syringe pump to control the movement of the syringe plunger. Compared with static HF-LPME, dynamic HF-LPME permitted much faster mass transfer of analytes through a thin organic film (as the solvent plug is withdrawn inside the syringe) to the solvent plug inside the HF (as the solvent plug is released into the HF), which resulted in higher enrichment factors. In another semiautomated two-phase HF-LPME system used for the extraction of pharmaceutical and endocrine disrupting compounds in sewage water samples, a 6-cm HF membrane filled with 40 mL of solvent was employed as a loop attached at one end to a stainless steel microfunnel guide, whereas the other end was kept unsealed and fixed in a small dent in the guide. This setup was then placed into a sample vial for the extraction of small sample volumes. On completion of the extraction, the sample vial was placed in a GC autosampler tray, and 1 mL of the extract was automatically taken from the HF and injected into the GC system by the autosampler.103 Very recently, Ouyang et al.104 explored a fully automated two-phase HF-LPME device that was applied to the kinetic calibration of carbaryl extraction in water and red wine samples. The device encompassed a 1.8 cm-long microporous HF inserted into one end of a thin micropipette tip (0.5– 10 mL) and firmly fixed to the needle-guiding tip (fixed in the sample vial) by heat. The other end of the micropipette was pressure-sealed, giving a final effective HF length of 1.5 cm. All extraction steps, including filling the extraction solvent (20 mL), transferring and agitating the sample, withdrawing and introducing the extraction phase into the GC injector, were performed automatically by a CTC CombiPal autosampler. With the aid of this device, the kinetics of HF-LPME absorption and desorption processes was extensively investigated. The kinetic calibration approach was successfully used to correct for matrix effects and showed that neither sample volume nor sampling time affected the feasibility of the calibration method. The automated HF-LPME technique has proved useful for determining the analyte distribution coefficient between a sample matrix and an extraction phase.

4.5

SUMMARY AND FUTURE OUTLOOK

The conclusions that can be drawn from the work presented in this chapter emphasize the miniaturization trends currently being pursued in modern analyte extraction techniques. The trends are focused mainly on miniaturization of the core idea of the extraction techniques utilized for analyte extraction from water samples. This has in turn promoted automation and hyphenation of extraction principles with on-line or off-line connection to analytical instruments. For instance, miniaturized liquid-phase extraction techniques (Section 4.2.1) have become very popular because of their simplicity, ease of use, and low solvent demand. However, these procedures suffer significantly from the vulnerability of the solvent microdrop to dislodgement. To circumvent the shortcomings of these techniques, downsized adsorptive solid-phase and solvent-free sorptive extraction systems (Sections 4.2.2 through 4.2.4) and also membrane-based setups (Sections 4.3 and 4.4) have been pursued as alternatives. Among the SPE designs is the fully automated MEPS device, the applications of which can be extended to the extraction of environmental aqueous samples. The solvent-free SPME technique has demonstrated a high degree of robustness coupled with outstanding performance, as a result of which it has become very popular and is used in a broad diversity of applications. Indeed, the SPME technique has become prevalent and is implemented in many different scientific disciplines. The polymeric membrane extraction systems, that is, MIMS, MESI, and PIME, have been extensively applied for sampling VOCs and SVOCs. In contrast, liquid membrane extraction

Modern Techniques of Analyte Extraction

89

configurations (SLM, MMLLE (ESy) and two-phase or three-phase HF-LPME have been widely and successfully employed in the extraction of a wide spectrum of analytes in different sample matrices. SLM extraction (also three-phase HF-LPME) selectively enriches ionizable polar to slightly polar analytes, whereas MMLLE is used primarily for extracting hydrophobic neutral analytes. The two techniques are thus regarded as complementary sampling procedures. The design of the flowing and automated setups of SLM and MMLLE are complicated, and there have been some teething troubles: analyte carryover, adsorption problems, and blockage of the narrow-diameter tubing used in flow systems have been reported. Hence, the simpler the SLM or MMLLE setups, the more robust and less problematic they will tend to be; for certain applications, however, setups based on nonautomated, nonflowing HF-based procedures might be preferable. It is very probable that the SLM technique will become widely utilized for selective and sensitive extractions (immunoaffinity-based ISLM design). Moreover, the ESTM technique based on equilibrium SLM is likely to be extensively investigated in the context of speciation studies in environmental samples, with the major focus being on characterizing the interaction of analytes and macromolecules (such as HAs). Furthermore, the SLM format is well suited for studying different types of transport mechanisms. The two-phase HF-MMLLE/HF-LPME procedure with potential automation is expected to achieve wide acceptance among researchers and experimentalists as it is direct and easy-to-use. This chapter has shown that many extraction techniques available today are based on the same principle but have been given different names. An IUPAC initiative is therefore needed for the unification of the subject nomenclature in order to avoid misunderstandings and enable unambiguous knowledge to be disseminated to young scholars.

ACRONYMS AND ABBREVIATIONS Aliquat 336 AMPA CE CFME D2EHPA DVB ECD ESDs Ee E ESTM ESy FID FIT-SPE FS GC HAs HF HF-LPME HPLC ISLM LC LDPE LLE LOD log Ko/w

methyltrioctylammonium chloride aminomethyl phosphonic acid capillary electrophoresis continuous-flow microextraction di-2-ethylhexyl phosphonic acid divinylbenzene electron capture detector equilibrium sampling devices enrichment factor extraction efficiency equilibrium sampling through membrane extracting syringe flame ionization detector fiber-in-tube solid-phase extraction flat sheet gas chromatography humic acids hollow fiber hollow-fiber liquid-phase microextraction high-performance liquid chromatograph immuno-supported liquid membrane liquid chromatography low-density polyethylene liquid–liquid extraction limit of detection logarithmic partition coefficient of analyte in octanol/water

90

LOQ LPME LVI MASE MEPS MESI MIMS MMLLE MS OCPs PAHs PBDEs PCBs PDMS PEEK PHWE PIME PP PTFE PTV PVDF SBSE SLM SME SPDE SPE SPME SVOCs TDU VOCs

Analytical Measurements in Aquatic Environments

limit of quantification liquid-phase microextraction large volume injection membrane-assisted solvent extraction microextraction in packed syringe membrane extraction with sorbent interface membrane inlet (introduction) mass spectrometry microporous membrane liquid–liquid extraction mass spectrometry organochlorine pesticides polycyclic aromatic hydrocarbons polybrominated diphenyl ethers polychlorinated biphenyls polydimethyl siloxane polyetheretherketone pressurized hot water extraction pulse introduction membrane extraction polypropylene polytetrafluoroethylene programmable temperature vaporizer polyvinylidene fluoride stir bar sorptive extraction supported liquid membrane solvent microextraction solid-phase dynamic extraction solid-phase extraction solid-phase microextraction semivolatile organic compounds thermal desorption unit volatile organic compounds

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36. Heringa, M.B., R.H.M.M. Schreurs, F. Busser, P.T. van der Saag, B. van der Burg, and J.L.M. Hermens. 2004. Toward more useful in vitro toxicity data with measured free concentrations. Environ. Sci. Technol. 38: 6263–6270. 37. Leslie, H.A., J.L.M. Hermens, and M.H.S. Kraak. 2004. Baseline toxicity of a chlorobenzene mixture and total body residues measured and estimated with solid-phase microextraction. Environ. Toxicol. Chem. 23: 2017–2021. 38. Leslie, H.A., T.L. Ter Laak, F.J.M. Busser, M.H.S. Kraak, and J.L.M. Hermens. 2002. Bioconcentration of organic chemicals: Is a solid-phase microextraction fiber a good surrogate for biota? Environ. Sci. Technol. 36: 5399–5404. 39. Lanno, R., T.W. La Point, J.M. Conder, and J.B. Wells. 2005. Application of solid-phase microextraction fibers as biomimetic sampling devices in ecotoxicology, Chapter 28. In: G.K. Ostrander (ed.), Techniques in Aquatic Toxicology, Vol. 2, pp. 511–522. Florida: Taylor & Francis-CRC Press. 40. Parkerton, T.F., M.A. Stone, and D.J. Letinski. 2000. Assessing the aquatic toxicity of complex hydrocarbon mixtures using solid phase microextraction. Toxicol. Lett. 112–113: 273–282. 41. Poerschmann, J., Z. Zhang, F.-D. Kopinke, and J. Pawliszyn. 1997. Solid phase microextraction for determining the distribution of chemicals in aqueous matrices. Anal. Chem. 69: 597–600. 42. Droge, S.T.J., T.L. Sinnige, and J.L.M. Hermens. 2007. Analysis of freely dissolved alcohol ethoxylate homologues in various seawater matrixes using solid-phase microextraction. Anal. Chem. 79: 2885–2891. 43. Baltussen, E., P. Sandra, F. David, and C. Cramers. 1999. Stir bar sorptive extraction (SBSE), a novel extraction technique for aqueous samples: Theory and principles. J. Microcolumn Sep. 11: 737–747. 44. Baltussen, E., C.A. Cramers, and P.J.F. Sandra. 2002. Sorptive sample preparation—a review. Anal. Bioanal. Chem. 373: 3–22. 45. David, F. and P. Sandra. 2007. Stir bar sorptive extraction for trace analysis. J. Chromatogr. A 1152: 54–69. 46. Kawaguchi, M., Y. Ishii, N. Sakui, N. Okanouchi, R. Ito, K. Inoue, K. Saito, and H. Nakazawa. 2004. Stir bar sorptive extraction with in situ derivatization and thermal desorption-gas chromatography-mass spectrometry in the multi-shot mode for determination of estrogens in river water samples. J. Chromatogr. A 1049: 1–8. 47. Oser, H., M.J. Coggiola, S.E. Young, D.R. Crosley, V. Hafer, and G. Grist. 2007. Membrane introduction/ laser photoionization time-of-flight mass spectrometry. Chemosphere 67: 1701–1708. 48. Creaser, C.S., D.J. Weston, and B. Smith. 2000. In-membrane preconcentration/membrane inlet mass spectrometry of volatile and semivolatile organic compounds. Anal. Chem. 72: 2730–2736. 49. Mendes, M.A. and M.N. Eberlin. 2000. Trace level analysis of VOCs and semi-VOCs in aqueous solution using a direct insertion membrane probe and trap and release membrane introduction mass spectrometry. Analyst 125: 21–24. 50. Thompson, A.J., A.S. Creba, R.M. Ferguson, E.T. Krogh, and C.G. Gill. 2006. A coaxially heated membrane introduction mass spectrometry interface for the rapid and sensitive on-line measurement of volatile and semi-volatile organic contaminants in air and water at parts-per-trillion levels. Rapid Commun. Mass Spectrom. 20: 2000–2008. 51. Ketola, R.A., T. Kotiaho, M.E. Cisper, and T.M. Allen. 2002. Environmental applications of membrane introduction mass spectrometry. J. Mass Spectrom. 37: 457–476. 52. Luo, Y.Z. and J. Pawliszyn. 2000. Membrane extraction with a sorbent interface for headspace monitoring of aqueous samples using a cap sampling device. Anal. Chem. 72: 1058–1063. 53. Segal, A., T. Gorecki, P. Mussche, J. Lips, and J. Pawliszyn. 2000. Development of membrane extraction with a sorbent interface-micro gas chromatography system for field analysis. J. Chromatogr. A 873: 13–27. 54. Liu, X. and J. Pawliszyn. 2005. On-site environmental analysis by membrane extraction with a sorbent interface combined with a portable gas chromatograph system. Int. J. Environ. Anal. Chem. 85: 1189–1200. 55. Juan, A.S., X. Guo, and S. Mitra. 2001. On-site and on-line analysis of chlorinated solvents in ground water using pulse introduction membrane extraction gas chromatography (PIME-GC). J. Sep. Sci. 24: 599–605. 56. Guo, X. and S. Mitra. 1999. Theoretical analysis of non-steady-state, pulse introduction membrane extraction with a sorbent trap interface for gas chromatographic detection. Anal. Chem. 71: 4587–4593. 57. Guo, X. and S. Mitra. 1999. Enhancement of extraction efficiency and reduction of boundary layer effects in pulse introduction membrane extraction. Anal. Chem. 71: 4407–4412. 58. Kou, D., A. San Juan, and S. Mitra. 2001. Gas injection membrane extraction for fast on-line analysis using GC detection. Anal. Chem. 73: 5462–5467.

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59. Hauser B. and P. Popp. 2001. Membrane-assisted solvent extraction of organochlorine compounds in combination with large-volume injection/gas chromatography-electron capture detection. J. Sep. Sci. 24: 551–560. 60. Einsle, T., H. Paschke, K. Bruns, S. Schrader, P. Popp, and M. Moeder. 2006. Membrane-assisted liquid– liquid extraction coupled with gas chromatography-mass spectrometry for determination of selected polycyclic musk compounds and drugs in water samples. J. Chromatogr. A 1124: 196–204. 61. Hauser, B., M. Schellin, and P. Popp. 2004. Membrane-assisted solvent extraction of triazines, organochlorine, and organophosphorus compounds in complex samples combined with large-volume injectiongas chromatography/mass spectrometric detection. Anal. Chem. 76: 6029–6038. 62. Audunsson, G. 1986. Aqueous/aqueous extraction by means of a liquid membrane for sample cleanup and preconcentration of amines in a flow system. Anal. Chem. 58: 2714–2723. 63. Jönsson, J.Å. and L. Mathiasson. 1999. Liquid membrane extraction in analytical sample preparation: I. Principles. Trends Anal. Chem. 18: 318–325. 64. Jönsson, J.Å., P. Lövkvist, G. Audunsson, and G. Nilvé. 1993. Mass transfer kinetics for analytical enrichment and sample preparation using supported liquid membranes in a flow system with stagnant acceptor liquid. Anal. Chim. Acta 277: 9–24. 65. Chimuka, L., L. Mathiasson, and J.Å. Jönsson. 2000. Role of octanol-water partition coefficients in extraction of ionisable organic compounds in a supported liquid membrane with a stagnant acceptor. Anal. Chim. Acta 416: 77–86. 66. Jönsson, J.Å. and L. Mathiasson. 2001. Membrane extraction techniques for sample preparation. In: E. Grushka (ed.), Advances in Chromatography, pp. 53–91. New York: Marcel Dekker. 67. Jönsson, J.Å. and L. Mathiasson. 2001. Membrane extraction in analytical chemistry. J. Sep. Sci. 24: 495–507. 68. Tudorache, M. and J. Emnéus. 2006. A micro-immuno supported liquid membrane assay (m-ISLMA). Biosens. Bioelectron. 21: 1513–1520. 69. Wang, X., C. Saridara, and S. Mitra. 2005. Microfluidic supported liquid membrane extraction. Anal. Chim. Acta 543: 92–98. 70. Lezamiz, J. and J.Å. Jönsson. 2007. Development of a simple hollow fibre supported liquid membrane extraction method to extract and preconcentrate dinitrophenols in environmental samples at ng L-1 level by liquid chromatography. J. Chromatogr. A 1152: 226–233. 71. Liu, J.-F., J.Å. Jönsson, and P. Mayer. 2005. Equilibrium sampling through membranes of freely dissolved chlorophenols in water samples with hollow fiber supported liquid membrane. Anal. Chem. 77: 4800–4809. 72. Jönsson, J.Å. and L. Mathiasson. 2000. Membrane-based techniques for sample enrichment. J. Chromatogr. A 902: 205–225. 73. Nilvé, G. 1992. Sample pretreatment methods for determination of acidic herbicides in water, with special emphasis on supported liquid membranes. PhD dissertation, Lund University, Sweden. 74. Dzygiel, P. and P. Wieczorek. 2001. Supported liquid membrane extraction of glyphosate metabolites. J. Sep. Sci. 24: 561–566. 75. Djane, N.-K., K. Ndung’u, F. Malcus, G. Johansson, and L. Mathiasson. 1997. Supported liquid membrane enrichment using an organophosphorus extractant for analytical trace metal determinations in river waters. Fresenius J. Anal. Chem. 358: 822–827. 76. Mulugeta, M. and N. Megersa. 2004. Carrier-mediated extraction of bipyridilium herbicides across the hydrophobic liquid membrane. Talanta 64: 101–108. 77. Romero, R. and J.Å. Jönsson. 2005. Determination of free copper concentrations in natural waters by using supported liquid membrane extraction under equilibrium conditions. Anal. Bioanal. Chem. 381: 1452–1459. 78. Romero, R., J.-F. Liu, P. Mayer, and J.Å. Jönsson. 2005. Equilibrium sampling through membranes of freely dissolved copper concentrations with selective hollow fiber membranes and the spectrophotometric detection of a metal stripping agent. Anal. Chem. 77: 7605–7611. 79. Thordarson, E., J.Å. Jönsson, and J. Emnéus. 2000. Immunologic trapping in supported liquid membrane extraction. Anal. Chem. 72: 5280–5284. 80. Tudorache, M., M. Rak, P.P. Wieczorek, J.Å. Jönsson, and J. Emnéus. 2004. Immuno-SLM—a combined sample handling and analytical technique. J. Immunol. Methods 284: 107–118. 81. Tudorache, M. and J. Emnéus. 2005. Selective immuno-supported liquid membrane (ISLM) extraction, enrichment and analysis of 2,4,6-trichlorophenol. J. Membr. Sci. 256: 143–149. 82. Tudorache, M., M. Co, H. Lifgren, and J. Emnéus. 2005. Ultrasensitive magnetic particle-based immunosupported liquid membrane assay. Anal. Chem. 77: 7156–7162.

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On-line automated sample preparation for liquid chromatography using parallel supported liquid membrane extraction and microporous membrane liquid–liquid extraction. J. Chromatogr. A 975: 211–217. 91. Sandahl, M., E. Úlfsson, and L. Mathiasson. 2000. Automated determination of vinclozolin at the ppb level in aqueous samples by a combination of microporous membrane liquid–liquid extraction and adsorption chromatography. Anal. Chim. Acta 424: 1–5. 92. Norberg, J., E. Thordarson, L. Mathiasson, and J.Å. Jönsson. 2000. Microporous membrane liquid–liquid extraction coupled on-line with normal-phase liquid chromatography for the determination of cationic surfactants in river and waste water. J. Chromatogr. A 869: 523–529. 93. Barri, T., S. Bergström, J. Norberg, and J.Å. Jonsson. 2004. Miniaturized and automated sample pretreatment for determination of PCBs in environmental aqueous samples using an on-line microporous membrane liquid–liquid extraction-gas chromatography system. Anal. 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A novel hollow-fibre microporous membrane liquid–liquid extraction for determination of free 4-isobutylacetophenone concentration at ultra trace level in environmental aqueous samples. J. Chromatogr. A 1157: 30–37. 98. Shen, G. and H.K. Lee. 2002. Hollow fiber-protected liquid-phase microextraction of triazine herbicides. Anal. Chem. 74: 648–654. 99. Jiang, X. and H.K. Lee. 2004. Solvent bar microextraction. Anal. Chem. 76: 5591–5596. 100. Wang, J.-X., D.-Q. Jiang, and X.-P. Yan. 2006. Determination of substituted benzenes in water samples by fiber-in-tube liquid phase microextraction coupled with gas chromatography. Talanta 68: 945–950. 101. Lee, H.S.N., M.T. Sng, C. Basheer, and H.K. Lee. 2007. Determination of degradation products of chemical warfare agents in water using hollow fibre-protected liquid-phase microextraction with in situ derivatisation followed by gas chromatography-mass spectrometry. J. Chromatogr. A 1148: 8–15. 102. Zhao, L. and H.K. Lee. 2002. 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5

Mineralization Techniques Used in the Sample Preparation Step Henryk Matusiewicz

CONTENTS 5.1 5.2

Introduction ........................................................................................................................ 95 Advanced Oxidation Processes for Water Sample Preparation .......................................... 96 5.2.1 UV Photo-Oxidation ............................................................................................... 97 5.2.2 Ozone Oxidation ..................................................................................................... 98 5.3 Microwave-Assisted Mineralization of Natural Waters ..................................................... 99 5.4 Conclusions ....................................................................................................................... 100 References .................................................................................................................................. 101

5.1

INTRODUCTION

Water is an essential resource for all living species, including human. Surface and subsurface water supplies accumulate many chemical constituents from both natural and anthropogenic sources. While knowledge about the effects of these accumulated impurities on biological, agricultural, and industrial systems is expanding, it is still limited in scope. It is therefore necessary to analyze a range of natural waters (surface waters, e.g., rivers, streams, lakes, reservoirs, oceans, and seas; precipitation, e.g., rain, dew, hail, and snow; groundwater), polluted waters (e.g., industrial effluents and sewage sludge), and purified waters (e.g., drinking water and distilled water). Many laboratories deal with the determination of heavy metals, carbon, nitrogen, and phosphorus in natural water samples. But such samples also contain numerous dissolved organic substances (mainly alcohols, aldehydes, carboxylic acids, and macromolecular compounds with several functional groups such as humic and fulvic acids) that could affect the complexation of the analyte or displace the retained metal complex from the stationary phase, so these competitive ligands need to be decomposed before instrumental analytical techniques can be applied. Therefore, the first step in the chemical analysis of a water sample is its proper preparation. Metal concentrations are determined using molecular spectrophotometric, atomic spectrometric, and electrochemical techniques. All of these require samples to be homogenous, or at least to contain the smallest possible amounts of organic matter that could interfere with the metal determination by interacting with the metal ions and the analytical reagents. Traditionally, decomposition of the sample in elemental analysis requires it to be mineralized in order to remove the organic content.1 Sample decomposition for total element determination therefore appears to be the recommended procedure on every occasion.

95

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This chapter presents an overview of sample treatment procedures [e.g., decomposition, digestion, mineralization, oxidation, ultraviolet (UV) decomposition, and ozonation] and discusses a range of analytical techniques for the mineralization of natural aquatic systems. Other samples, such as effluents and sewage sludge, are beyond the scope of this contribution and will not be discussed here.

5.2 ADVANCED OXIDATION PROCESSES FOR WATER SAMPLE PREPARATION Traditionally, pretreatment of a water sample in elemental analysis requires mineralization and/or dissolution of the matrix in order to remove the organic content. The presence of dissolved organic matter (DOM) in samples makes the application of electrochemical and atomic spectrometric techniques (AAS, OES, AFS) difficult or even impossible. Hence, the proper preparation of a sample, in particular the elimination of organic matter, is of great importance. Some analytical procedures include a wet digestion step, consisting of sample evaporation followed by sample heating with concentrated acids. However, there are several drawbacks to this classical approach: (i) the acids can themselves be a source of contamination, and they constitute a hazard; (ii) the sample preparation methods are time-consuming; and (iii) there is a chance of analyte loss through volatilization or retention by an insoluble residue. In routine analytical laboratories, the use of advanced oxidation processes (AOPs) is an emerging alternative to conventional sample treatments2 for analytical and environmental chemists. AOPs involve the in situ generation of highly potent chemical oxidants, such as the hydroxyl radical (OH*). Several processes have been applied in analytical sample pretreatment: homogenous UV irradiation, either by direct irradiation of the sample or photolysis mediated by an appropriate chemical reagent; ozone; and ultrasonic irradiation. A variety of AOPs ensures compliance of specific treatment requirements with optimum treatment technologies (Table 5.1). Most AOPs take place at room temperature with the organic matter present in the sample. The results are various: decrease of DOM; inactivation of the sequestering agents present; destruction of the metal-organic compounds; diminished oxidant properties of the solution. The equipment is usually inexpensive, readily available, and does not introduce impurities in the sample. In addition, only minimal skills are required of the operator. As a result of the mild conditions used with AOPs (e.g., smaller quantities and lower concentrations of reagents and low temperature), the risk of analyte loss and the hazard to the chemist are less than with traditional procedures. Moreover, sample preparation is not so time-consuming. The acids and other reagents used in AOPs should be of sufficient purity to result in a minimal blank contribution to the final result. Most chemical reagent manufacturers supply a range of reagents suitable for low-level electrochemical and atomic spectroscopic analysis, and it is these that should be used. Blank values are dependent upon the type of AOP but

TABLE 5.1 Representative Advanced Oxidation Processes UV/O2 UV/H2O2 UV/O3 O3/H2O2/UV

Photolysis UV peroxide process Ozonolysis Peroxon process

UV/Fe3+/O2

Fe3+-catalyzed photolysis Photoassisted Fenton process

UV/H2O2/Fe3+ UV/TiO2/O2

Photocatalysis

Mineralization Techniques Used in the Sample Preparation Step

97

are typically less than the criterion of detection, except for ubiquitous elements such as calcium, magnesium, sodium, and zinc.

5.2.1

UV PHOTO-OXIDATION

UV digestion is a clean sample preparation method, not requiring large amounts of oxidants. UV photo-oxidation, that is, UV digestion, photolysis, UV irradiation, is utilized mainly in conjunction with uncontaminated or slightly contaminated natural water matrices (aqueous solutions). Liquids are decomposed by UV radiation in the presence of small amounts of hydrogen peroxide, acids (mainly HNO3), or peroxydisulfate.3 UV photo-oxidation minimizes the use of hot, hazardous reagents, for example, perchloric and sulfuric acids. DOM and the complexes of the chemical elements are decomposed to yield free metal ions. The digestion vessel should be placed as close as possible to the UV lamp (low, medium, and high pressure) to ensure a high photon flux; the lamp has an emission spectrum with a maximum at 254 nm. In photolysis, the digestion mechanism involves the formation, initiated by the UV radiation, of OH* radicals from both water and hydrogen peroxide molecules.3 These reactive radicals are able to oxidize to carbon dioxide and water, the organic matter present in simple matrices containing up to about 100 mg/L of carbon. Complete elimination of the matrix effect is, of course, possible only with simple matrices or by combining photolysis with other digestion techniques such as ozonation. The method does not oxidize all the organic components that could be present in water; chlorinated phenols, nitrophenols, hexachlorobenzene, and similar compounds are only partly oxidized. Effective cooling of the sample is essential, because losses may otherwise be incurred with highly volatile elements. The addition of hydrogen peroxide may need to be repeated several times to produce a clear sample solution. Modern UV digestion systems are commercially available (Table 5.1).3 Photochemical operations offer several routes of hydroxyl radical formation by UV irradiation. The formation of hydroxyl radicals by irradiation of samples doped with hydrogen peroxide or ozone is the state-of-the-art in water treatment. Two comprehensive reviews cover the historical development of the UV photo-oxidation technique as a pretreatment step in the inorganic analysis of natural waters, its principles and the equipment available, and its principal applications in the analytical field.3,4 They include tables summarizing the elements determined, the analytical techniques used, and the sample matrices studied. Only a few of the numerous UV irradiation-based digestion methods to have been published meet the requirement of being both efficient and error-free. UV photo-oxidation appears to be irreplaceable for water analysis, because of the low concentration of the elements investigated; the application of other means of digestion could cause contamination. In these UV methods, a small amount of hydrogen peroxide, the source of oxygen-free radicals, has to be added to the acidified sample. In general, the sample needs to be boiled from 1 to 4 h, depending on the organic content in the water, in order to destroy this matter without producing perceptible errors. UV digestion is a clean sample preparation method, as it does not require the use of large amounts of oxidants. Furthermore, the method is effective and can be readily incorporated into flow injection manifolds. On-line photo-oxidation (UV irradiation) has also been used for the digestion of organic compounds in waters. The sample flows through a tube (PTFE, quartz) coiled around a fixed UV lamp(s) in the presence of O3, H2O2, K2S2O8, or HNO3, in which the UV irradiation acts as a catalyst. A short review of such flow systems has appeared recently.3 Flow systems are becoming more popular in analysis because of their ease of automation, speed, small volume of sample, and elegance; the future in this respect looks promising. Apart from acidification, UV irradiation is the only preliminary preparative step in voltammetric determinations; it may be required to degrade organic substances binding trace metals in the form of inert complex species. The analysis of samples from natural waters may be significantly affected by the binding capacity of such dissolved organic substances. Table 5.2 lists the most relevant analytical applications of UV photo-oxidation.

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TABLE 5.2 Published Selected UV Photo-Oxidation Techniques Sample Type

Condition of Photo-Oxidation

Natural water

UV lamp 150 W, t = 12 h, pH 2, addition of H2O2 UV lamp 900 W, a few drops of 30% H2O2 and 0.004 M H2SO4, t = 1.5–2 h

Fresh water

Elements Determined

Analytical Technique

Reference

Cu, Hg

DPASV-RDE-Au

5

P

6

7

Water

UV lamp 1200 W, flow system, t = 15 min, addition of K2S2O8 or H2O2, variable pH

As

Colorimetric determination by molybdenum blue method HG-AAS

Fresh water

UV lamp 6 W, flow system, t = 40 min UV sample pretreatment, flow system, 0.14 M K2S2O8

Cd, Cu, Pb

FAAS, ICP-MS

8

Hg

FI-CV-AAS

9

UV lamp 700 W, flow system, t = 100 s, 0.1 M H2SO4/0.1 M NaOH UV lamp 8 W, flow system, 0.5% K2Cr2O7/8% HCl

As

FI-HG-AAS

10

Hg

FI-CV-AAS

11

River water Sea water Sea water Sea water

UV lamp 15 W (t > 24 h) and 400 W (t = 30 min)

Cd, Cu, Hg, Pb

FAAS, CV-AAS

12

Natural water

UV lamp 150 W, t = 2–3 h, pH 2, addition of H2O2 UV lamp 150 W, pH 1

Cd, Cu, Pb, Zn

DPASV-HMDE

13

Bi, Sb

DPASV-HMDE

14

UV lamp 1000 W, t = 2–10 min, pH 2, addition of H2O2

Cd, Cu, Pb, Zn

DPASV-HMDE

15

UV lamp 500 W, t = 30 min, pH 2, addition of H2O2 In-line UV-digestion, lamp 100 (1000) W, addition of H2O2, pH 8.1; 2.5

Cd, Co, Cu, Ni, Pb, Zn

DPASV

16

Cr, Cu, Ni

ASV-HMDE

17

Hg

CV-AAS

18

River water, snow River water Natural waters Sea water River and pond waters

UV lamp 30 W, t = 20 min, addition of K2S2O8

Notes: DP-ASV, differential-pulse anodic stripping voltammetry; RDE-Au, rotating gold electrode; HG-AAS, hydride generation atomic absorption spectrometry; FAAS, flame atomic absorption spectrometry; FI-CV-AAS, flow-injection cold-vapor atomic absorption spectrometry; and HMDE, hanging mercury drop electrode.

5.2.2

OZONE OXIDATION

Ozone oxidation (ozonation) is very effective in sample treatment and remarkably active in destroying natural organic compounds prior to elemental determination.19 Ozone readily decomposes to produce radicals, which are believed to be responsible for the majority of the observed reactivity. It reacts at room temperature with the organic matter present in the sample and also renders inactive any sequestering agents present. It can be generated from the oxygen present in the air, an inexpensive and readily available procedure, and does not harbor impurities. Ozone is produced by either silent electrical discharge or the UV radiation method, the former being the more usual method.

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TABLE 5.3 Trace Metal Determination after Ozone Sample Treatment Sample Type

Condition of Ozonation

Natural water

Samples in acetate buffer, pH 4.7, 1 h ozonation Samples acidified to pH 2 with HCl, ozonation time ranges from 30 to 60 min

River water Geothermal water Water Water

Ozonation time ranges from 15 to 60 min, sample in 0.2 M HCl A small ozonizer was developed, 0.5 mL, ozonation time 30 s, pH > 7

Elements Determined

Analytical Technique

Reference

Cd, Pb

ASV

20

Cu

ASV

21

Hg Hg

CV-AAS CV-AAS

22 23

Hg

CV-AAS

24

Notes: ASV, anodic stripping voltammetry and CV-AAS, cold-vapor atomic absorption spectrometry.

When aqueous solutions are treated with ozone for several hours, there is significant sample evaporation: the rate of this process depends on the initial sample volume and the average temperature of the sample during the period of ozonolysis. The time required for ozone application is considerably longer than that needed with other AOPs, such as UV irradiation. Table 5.3 sets out the applications of ozone for the determination of elements in water; there are only a few such applications, despite the efficiency of ozone in decomposing organic matter.

5.3 MICROWAVE-ASSISTED MINERALIZATION OF NATURAL WATERS Wet digestion with chemical oxidants such as nitric acid, sulfuric acid, perchloric acid, or hydrogen peroxide has been used to decompose DOM in aqueous solutions. A serious drawback of this approach, however, is the need to add large concentrations of oxidants to the sample, which must then be decreased after digestion (by evaporation or sample dilution) to meet the conditions required for analysis. It is preferable to use a less complex digestion method that gives complete and consistent recovery but is still compatible with the analytical methodology and with the metal to be analyzed. Nitric acid decomposes most water samples in an appropriate form, and nitrate is also an acceptable matrix for most chemical analysis techniques. As a general rule, HNO3 is only used for easily oxidized natural water samples. Relatively few studies have investigated the application of microwave-assisted digestion for the determination of elements in water samples (Table 5.4). This is because natural water samples (rivers, raw, and drinking waters), containing minimal amounts of solid material, require a relatively mild wet digestion pretreatment procedure; in contrast, samples that contain significant amounts of solid material such as effluents and sewage sludge require more vigorous procedures. However, optimal conditions cannot be achieved when microwave digestion is applied to the analysis of water, since comparatively large volumes of sample are used and, as a consequence, the digestion reagents are much diluted. Their diminished decomposition power may be insufficient to mineralize completely all the components of the sample. This limitation is not always evident if the sample solutions are eventually analyzed by atomic absorption or plasma excitation, as these techniques possess a considerable inherent decomposing power. They are, therefore, capable of evaluating incompletely digested sample solutions.

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TABLE 5.4 Microwave-Assisted Digestion Procedures for Water Samples Sample Type

Elements Determined

Reagents Used

Water

Se

HCl

Water

Se

HCl

Environmental waters

As, Bi, Hg, Pb, Sn

KBrO3-KBr-HCl

Water

Se

KBr-HCl

Mineral and sea waters Surface waters

As

K2S2O8-NaOH

Geothermal fluids Rain water Lake, river, and rain waters

Al, As, Be, Ca, HNO3 Cu, Cd, Fe, K, Li, Mg, Mn, Na, Pb, Sn, Sr, Zn Fe H2O2 Pd Hg

HCl-HNO3-HF, HClO4, aqua regia HCl

Microwave System Prolabo Microdigest 301 Prolabo Microdigest 301 Prolabo Maxidigest MX-350 Milestone MLS-1200 MEGA Domestic oven

Digestion Method

Reference

HG-AAS

25

HG-AFS

26

FI-CVAAS, HG-AAS HG-AAS

27

28

On-line oxidation Pressure digestion

HG-AAS

29

FAAS, GF-AAS

30

Domestic oven

Flow system

ET-AAS

31

Multiwave 3000

Microwave-UV digestion On-line pretreatment

FI-ET-AAS

32

CV-AAS

33

CEM MDS-81D

Prolabo Maxidigest MX-350

On-line digestion On-line digestion On-line digestion

Analysis Technique

On-line pretreatment

Notes: HG-AAS, hydride generation atomic absorption spectrometry; HG-AFS, hydride generation atomic fluorescence spectrometry; FI-CV-AAS, flow-injection cold-vapor atomic absorption spectrometry; FAAS, flame atomic absorption spectrometry; GF-AAS, graphite furnace atomic absorption spectrometry; and ET-AAS, electrothermal atomic absorption spectrometry.

5.4

CONCLUSIONS

Owing to the very low concentration of trace elements in natural waters, decomposition of interfering substances is recommended in order to eliminate matrix effects. Under these conditions, the total concentration of trace elements can be measured with an acceptable accuracy by skilled analysts in suitable laboratories. In the analytical laboratory, AOPs and microwave-assisted digestion techniques are now important and powerful tools in the pretreatment of natural water samples for elemental spectrometry. AOPs are effective at extracting a large number of inorganic analytes; their ability to decompose the organic matter in a sample as well as simplicity, economy, and safety are further advantages. Ozonolysis as a water sample treatment procedure eliminates mainly the surface-active properties of organic matter rather than degrading the matter itself. Compared with the state-of-the-art H2O2/ UV process, which must be operated with a surplus of oxidizer, microwave-assisted digestion can be operated at moderate microwave power. A novel microwave-assisted high-temperature UV digestion procedure has been developed for the accelerated decomposition of interfering dissolved organic carbon prior to trace element determination in water samples. It is a technique that has significantly

Mineralization Techniques Used in the Sample Preparation Step

101

improved the performance of UV digestion (oxidation) and is especially useful in ultratrace analysis because of its extremely low risk of contamination.34,35

REFERENCES 1. Matusiewicz, H. 2003. Wet digestion methods. In: Z. Mester and R. Sturgeon (eds), Sample Preparation for Trace Element Analysis, pp. 193–233. Amsterdam: Elsevier. 2. Capelo-Martínez, J.L., P. Ximénez-Embún, Y. Madrid, and C. Cámara. 2004. Advanced oxidation processes for sample treatment in atomic spectrometry. Trends Anal. Chem. 23: 331–340. 3. Golimowski, J. and K. Golimowska. 1996. UV-photooxidation as pretreatment step in inorganic analysis of environmental samples. Anal. Chim. Acta 325: 111–133. 4. Maher, W. and L. Woo. 1998. Procedures for the storage and digestion of natural waters for the determination of filterable reactive phosphorus, total filterable phosphorus and total phosphorus. Anal. Chim. Acta 375: 5–47. 5. Sipos, L., J. Golimowski, P. Valenta, and H.W. Nürnberg. 1979. New voltammetric procedure for the simultaneous determination of copper and mercury in environmental samples. Fresenius Z. Anal. Chem. 298: 1–8. 6. Henriksen, A. 1970. Determination of total nitrogen, phosphorus and iron in fresh water by photooxidation with ultraviolet radiation. Analyst 95: 601–608. 7. Atallah, R.H. and D.A. Kalman. 1991.On-line photo-oxidation for the determination of organoarsenic compounds by atomic-absorption spectrometry with continuous arsine generation. Talanta 38: 167–173. 8. Guéguen, C., C. Belin, B.A. Thomas, F. Monna, P.Y. Favarger, and J. Dominik. 1999. The effect of freshwater UV-irradiation prior to resin preconcentration of trace metals. Anal. Chim. Acta 386: 155–159. 9. Wurl, O., O. Elsholz, and J. Baasner. 2000. Monitoring of total Hg in the river Elbe: FIA-device for on-line digestion. Fresenius J. Anal. Chem. 366: 191–195. 10. Cabon, J.Y. and N. Cabon. 2000. Determination of arsenic species in seawater by flow injection hydride generation in situ collection followed by graphite furnace atomic absorption spectrometry. Stability of As(III). Anal. Chim. Acta 418: 19–31. 11. Wurl, O., O. Elsholz, and R. Ebinghaus. 2001. On-line determination of total mercury in the Baltic Sea. Anal. Chim. Acta 438: 245–249. 12. Vasconcelos, M.T.S.D. and M.F.C. Leal. 1997. Speciation of Cu, Pb, Cd and Hg in waters of the Oporto coast in Portugal, using pre-concentration in a chelamine resin column. Anal. Chim. Acta 353: 189–198. 13. Golimowski, J., A.G.A. Merks, and P. Valenta. 1990. Trends in heavy metal levels in the dissolved and particulate phase in the Dutch Rhine-Meuse (MAAS) delta. Sci. Total Environ. 92: 113–127. 14. Postupolski, A. and J. Golimowski. 1991. Trace determination of antimony and bismuth in snow and water samples by stripping voltammetry. Electroanal. 3: 793–797. 15. Labuda, J., D. Saur, and R. Neeb. 1994. Anodic stripping voltammetric determination of heavy metals in solutions containing humic acids. Fresenius J. Anal. Chem. 348: 312–316. 16. Kolb, M., P. Rach, J. Schäfer, and A. Wild. 1992. Investigation of oxidative UV photolysis. I. Sample preparation for the voltammetric determination of Zn, Cd, Pb, Cu, Ni and Co in waters. Fresenius J. Anal. Chem. 342: 341–349. 17. Achterberg, E.P. and C.M.G. van den Berg. 1994. In-line ultraviolet-digestion of natural water samples for trace metal determination using an automated voltammetric system. Anal. Chim. Acta 291: 213–232. 18. Nagashima, K., T. Murata, and K. Kurihara. 2002. Pretreatment of water samples using UV irradiationperoxodisulfate for the determination of total mercury. Anal. Chim. Acta 454: 271–275. 19. Clem, R.G. and A.F. Sciamanna. 1975. Styrene impregnated, cobalt-60 irradiated, graphite electrode for anodic stripping analysis. Anal. Chem. 47: 276–280. 20. Clem, R.G. and A.T. Hodgson. 1978. Ozone oxidation of organic sequestering agents in water prior to the determination of trace metals by anodic stripping voltammetry. Anal. Chem. 50: 102–110. 21. Filipovic´-Kovacˇevic´, Ž. and L. Sipos. 1998. Voltammetric determination of copper in water samples digested by ozone. Talanta 45: 843–850. 22. Sakamoto, H., J. Taniyama, and N. Yonehara. 1997. Determination of ultra-trace amounts of total mercury by gold amalgamation-cold vapor AAS in geothermal water samples by using ozone as pretreatment agent. Anal. Sci. 13: 771–775.

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23. Anthemidis, A.N., G.A. Zachariadis, and J.A. Stratis. 2004. Development of a sequential injection system for trace mercury determination by cold vapour atomic absorption spectrometry. Talanta 64: 1053–1057. 24. Sasaki, K. and G.E. Pacey. 1990. The use of ozone as the primary digestion reagent for the cold vapor mercury procedure. Talanta 50: 175–181. 25. Pitts, L., P.J. Worsfold, and J. Hill. 1994. Selenium speciation—a flow injection approach employing online microwave reduction followed by hydride generation-quartz furnace atomic absorption spectrometry. Analyst 119: 2785–2788. 26. Pitts, L., A. Fisher, P. Worsfold, and S.J. Hill. 1995. Selenium speciation using high-performance liquid chromatography-hydride generation atomic fluorescence with on-line microwave reduction. J. Anal. At. Spectrom. 10: 519–520. 27. Tsalev, D.L., M. Sperling, and B. Welz. 1992.On-line microwave sample pre-treatment for hydride generation and cold vapour atomic absorption spectrometry. Part 2. Chemistry and applications. Analyst 117: 1735–1741. 28. González LaFuente, J.M., M.L. Fernández Sánchez, J.M. Marchante-Gayón, J.E. Sánchez Uria, and A. Sanz-Medel. 1996. On-line focused microwave digestion-hydride generation of inorganic and organic selenium. Spectrochim. Acta Part B 51: 1849–1857. 29. López-Gonzales, M.A., M.M. Gómez, C. Cámara, and M.A. Palacios. 1994. On-line microwave oxidation for the determination of organoarsenic compounds by high-performance liquid chromatographyhydride generation atomic absorption spectrometry. J. Anal. At. Spectrom. 9: 291–295. 30. Paukert, T. and Z. Sirotek. 1993. A study of the microwave treatment of water samples from the Elbe River, Bohemia, Czech Republic. Chem. Geol. 107: 133–144. 31. Burguera, J.L., M. Burguera, and C.E. Rondon. 1998. Automatic determination of iron in geothermal fluids containing high dissolved sulfur-compounds using flow injection electrothermal atomic absorption spectrometry with an on-line microwave radiation precipitation–dissolution system. Anal. Chim. Acta 366: 295–303. 32. Limbeck, A. 2006. Microwave-assisted UV-digestion procedure for the accurate determination of Pd in natural waters. Anal. Chim. Acta 575: 114–119. 33. Welz, B., D.L. Tsalev, and M. Sperling. 1992. On-line microwave sample pretreatment for the determination of mercury in water and urine by flow-injection cold-vapour atomic absorption spectrometry. Anal. Chim. Acta 261: 91–103. 34. Florian, D. and G. Knapp. 2001. High-temperature, microwave-assisted UV digestion: A promising sample preparation technique for trace element analysis. Anal. Chem. 73: 1515–1520. 35. Matusiewicz, H. and E. Stanisz. 2007. Characteristics of a novel UV-TiO2-microwave integrated irradiation device in decomposition processes. Microchem. J. 86: 9–16.

6

Biota Analysis as a Source of Information on the State of Aquatic Environments J.P. Coelho, A.I. Lillebø, M. Pacheco, M.E. Pereira, M.A. Pardal, and A.C. Duarte

CONTENTS 6.1 6.2

Introduction ...................................................................................................................... Choice of Species .............................................................................................................. 6.2.1 Primary Producers ................................................................................................ 6.2.2 Suspension Feeders ............................................................................................... 6.2.3 Sediment Dwellers ................................................................................................ 6.2.4 Pelagic Species ..................................................................................................... 6.3 Assessment Strategies ....................................................................................................... 6.3.1 Accumulation and Partitioning of Contaminants in Plants .................................. 6.3.2 Differential Tissue Analysis in Animals .............................................................. 6.4 Supplementary Methodologies ......................................................................................... 6.4.1 Oxidative Stress .................................................................................................... 6.4.2 Metallothioneins ................................................................................................... 6.5 Conclusions ....................................................................................................................... References ..................................................................................................................................

6.1

103 104 105 106 107 108 109 110 110 112 112 113 115 115

INTRODUCTION

An increased international awareness toward an assessment of the current status of aquatic environments and their protection has emerged as a result of multiple anthropogenic pressures, such as human population growth, progressive industrialization, and intensive agricultural practices. Initially, such an assessment was focused on the abiotic fractions of the environment, the dissolved fraction of the water column, and sediments. But the monitoring of dissolved contaminants is methodologically challenging, primarily because of limitations in analytical methods (capability of quantification), and also as a consequence of the typically low concentrations, not to mention the tendency for samples to become contaminated during collection or analysis.1 Furthermore, levels of dissolved contaminants are extremely variable and depend not only on season,2,3 but on factors such as tidal cycles4 and river flow5 as well. So a really accurate environmental assessment would require intensive, costly, and time-consuming monitoring programs.1,2 Finally, we need to mention that total dissolved contaminant concentrations are in fact not an accurate measure either of the fraction available to organisms or of that responsible for toxicity and bioaccumulation problems.

103

104

Analytical Measurements in Aquatic Environments

The same is true for sediments. Total contaminant concentrations in sediments do not reflect their bioavailability to organisms, which can be affected by numerous variables such as sediment geochemistry, particle size, or organic matter content.1,6–8 Nevertheless, the fact that contaminants accumulate in sediments is an advantage for monitoring, given that the relevant methodologies are more reliable and the matrix less prone to contamination.1 Moreover, sediment contaminant levels are more stable and may provide a historical record of contaminant load.9–11 The extent to which sediment contaminants are available to aquatic organisms is a current research topic in which different methodologies are applied—from sequential extraction methods8,12 to studies on assimilation efficiencies and gut juice extractions.7,13 In view of the limitations associated with the monitoring of dissolved and sediment-bound contaminants, the use of biota as a source of information on the quality of aquatic environments was suggested, and it has now become a widely accepted methodology for assessing contaminant bioavailability. Such an approach provides a time-integrated measure of contaminant availability to organisms, is easily measurable owing to the generally higher levels found in tissues, and is not prone to accidental contamination; it can therefore remove some of the limitations associated with water and sediment monitoring strategies.1 The recent approval and implementation of the European Water Framework Directive further emphasizes the role of biota as a tool for assessing aquatic environmental quality, in that it strives not only for the improvement of the chemical quality status of water bodies but also for the rehabilitation of their ecological status. In the light of these recommendations, it becomes essential to use biota to assess not only the chemical status of water bodies through contaminant load analysis, but also their ecological status, in what must be an integrated, multidisciplinary approach. Three fundamental questions arise if this kind of methodology is to be invoked to monitor the health of water bodies: (a) Which of the countless species inhabiting any given aquatic ecosystem should be used as a source of environmental information? (b) Which assessment strategy should be employed: the analysis of entire organisms or specific tissue discrimination? (c) Which supplementary methodologies can be applied to complement the information supplied by biota analysis so as to facilitate a more rigorous evaluation of the state of the ecosystem? This chapter presents an overview of the different approaches and methodologies used for gathering environmental information from biota analysis. The choice of species, the analysis of individual whole organisms or selected tissues, and the study of the partition of contaminants within organisms to subcellular methods such as stress-related enzymatic studies and metal-binding proteins [metallothioneins (MTs) or phytochelatins (PCs)] will be discussed as a way of responding to these three major issues. Of the multitude of contaminants present in aquatic environments, we shall focus principally on metals; these are regarded as one of the main and most toxic groups of environmental contaminants, and very liable to bioaccumulate. But even though many of the aspects and methodologies are discussed in the context of metals, they are equally applicable to other classes of contaminant. Case studies will be presented, essentially from an extensively studied system (the Ria de Aveiro coastal lagoon, west coast of Portugal), where a well-defined anthropogenic mercury contamination gradient has justified numerous studies on the bioaccumulation of contaminants and its effects.

6.2

CHOICE OF SPECIES

The use of bioindicators and biomonitors for gathering environmental information is currently widespread, although some abuse of these terms is customary. The terms bioindicator and biomonitor are commonly but incorrectly taken to be synonymous: a bioindicator provides qualitative information on the quality of the environment, whereas a biomonitor supplies quantitative data on environmental contamination.14 This section focuses on the latter, since the trace metal content of biota has been commonly used in biomonitoring programs of metal pollution in the marine environment and is considered to provide a time-integrated measure of metal bioavailability.1,15,16

Biota Analysis as a Source of Information on the State of Aquatic Environments

105

In a review on the subject, Rainbow and Phillips15 enumerate the desirable properties for a suitable biomonitor species. According to these authors, a suitable biomonitor should be sessile, abundant, and easy to identify and sample. They also consider resistance and tolerance to stress and environmental variations to be important features, as is the absence of regulation in the accumulation process. However, taking into account the different pathways by which organisms are exposed to contaminants,15,17,18 species-specific traits, and the specificity of any given contaminant, the suitability of different species as biomonitors may differ. The solution, according to Rainbow and Phillips,15 would be to use not one biomonitor species, but a suite of biomonitors that would reflect the overall bioavailability of contaminants in the various compartments of an ecosystem (dissolved and particulate fractions of the water column and sediments). Also, since some contaminants are transferred from prey to predator via biomagnification processes, it would be useful to choose a set of biomonitors involving different trophic levels.

6.2.1

PRIMARY PRODUCERS

Macroalgae have generally been considered efficient biomonitors of dissolved metal sources,2,15,19–23 but there appear to be two major limitations to their use. Some genera, especially green macroalgae from the genus Ulva, show marked morphological polymorphism, which makes taxonomic identification problematic. In view of the variability in contaminant accumulation between even closely related species, some bias may result from using species from this genus for biomonitoring studies.19 The other crucial limitation of macroalgae stems from their surfaces becoming contaminated by epiphytes and particulate matter, which may give rise to overestimations of contaminant accumulation.24 The observed positive correlations with sediment contamination rather than with dissolved fraction contaminant levels25,26 may in part reflect surface contamination by highly contaminated fine particulates. The washing techniques to cope with this limitation are not standardized,19,24 and the use of correction factors (for instance, the Al content, an indicator of lithogenic particles) does not cover the contribution of adherent epiphytes to the overall contaminant accumulation. Speciesspecific traits should also be taken into account when choosing an algal species, since free-floating algae (mainly green macroalgae like Ulva) will be more mobile and, unlike the more sessile strains, may not reflect the environmental contamination at the site of collection.23 Lastly, the contaminant to be monitored may also influence the choice of algal biomonitor, since some species may be more suitable for specific contaminants. Coelho et al.23 studied the response of dominant species of macroalgae (Fucus vesiculosus, Gracilaria verrucosa, and Enteromorpha intestinalis) to a mercury contamination gradient in a temperate estuary. While for total mercury the three species showed a similar pattern, the organic mercury fraction (methylmercury and other organic mercury compounds) was species-specific and displayed opposing trends with distance to contamination source (Figure 6.1); their suitability as biomonitors for this contaminant is thus questionable. Fewer data are available on contaminant accumulation by sea grasses than for macroalgae. Nevertheless, sea grasses of several genera have been selected as biomonitors, with special focus on the genera Posidonia and Zostera.19 In contrast to algae, sea grasses may reflect both dissolved contaminant concentrations and sediment contaminant loads, since they may accumulate these substances through both the root system and the aerial parts. This was observed in a study by Lafabrie et al.27 of the seagrass Posidonia oceanica in the Mediterranean, where metals accumulated preferably in the blades, which suggested uptake from the water column. In another study, the same species was found to reflect contamination in both the water column (Cd and Pb) and the sediment (Co, Cr, Hg, and Ni).28 Such differential uptake routes may lead to uncertainty about the source of contamination responsible for tissue contamination. Salt marsh plants, in turn, reflect mainly sediment contaminant loads rather than the dissolved fraction, given their uptake route via the root system. Some research has been performed on the genera Spartina and Phragmites,29–33 which accumulate metals essentially in the underground

106

Analytical Measurements in Aquatic Environments Enteromorpha intestinalis 12

Gracilaria verrucosa

Fucus vesiculosus R2 = 0.92

10 8 6 4

R2 = 0.92

2

R2 = 0.15

0 4

5

6 Distance to source (km)

7

8

FIGURE 6.1 Organic mercury fraction (%) in three macroalgae species along a mercury gradient in a temperate estuary. (After Coelho et al. 2005. Estuar. Coast. Shelf Sci. 65: 492–500. With permission.)

biomass and restrict their translocation to the photosynthetic parts. Roots would therefore be a potential biomonitor of sediment contaminants, which is not always the case since salt marsh plants actively modify the environment around the roots, by oxygen transportation and its release in the root system, altering the chemical equilibrium and contaminant bioavailability. Furthermore, many salt marsh plants exhibit marked seasonality, which can lead to increased bias and possibly mask correlations with environmental contamination. The use of sea grasses and salt marsh plants to gather environmental information will be discussed later in the chapter.

6.2.2

SUSPENSION FEEDERS

To assess the bioavailability of contaminants in the water column (in both dissolved and suspended particulates), the usual and most reliable option is to use suspension feeders, the best known of which are mussels. The Mussel Watch Program in the United States has been monitoring contaminant concentrations in mussels and oysters since 1986,34–36 and similar programs have been implemented in other areas of the globe.37–39 These take advantage of the worldwide distribution of the genus Mytilus and its favorable characteristics for biomonitoring purposes, such as high tolerance to contamination and salinity fluctuations, sessile existence, and ease of collection.15,34 The principal limitation regarding the use of mussels (the genus Mytilus in temperate waters and the closely related genus Perna in tropical areas) is the coexistence of closely related species, taxonomically difficult to identify, which may bring the validity of data intercomparisons into question,15 as was discussed by Szefer et al.40 Despite this shortcoming, such an approach provides invaluable information about the ecological status of aquatic ecosystems, and can supply long-term databases from which the temporal trends of contaminant bioavailability at any given location can be inferred, provided that the same species is sampled.34–36,39 To minimize physiology-associated bias, certain sampling guidelines should be followed. The sampling season ought to be invariable and outside the reproductive periods, preferably in winter, since many lipophilic compounds may be released during spawning owing to the high lipid content of eggs and sperm.34 Also, sampling should focus on a predetermined size range, given the many years’ lifespan of mussels, in order to reduce disparities in exposure time to contaminants, which could artificially mask any existing environmental trend. Finally, the sampling site should remain unchanged in order to ensure comparable exposure conditions to contaminants.34 A variation on this theme is the transplantation of individuals to desired monitoring sites, an active biomonitoring method. In this approach, however, some of the inherent natural variability is reduced by ensuring comparable biological samples.41–44 Moreover, exposure time is controlled, the organisms are statistically similar, and the method is independent of the natural occurrence of the

Biota Analysis as a Source of Information on the State of Aquatic Environments

107

species selected; on the other hand, the experimental design and logistics are more complex and subject to disturbances during exposure.41

6.2.3

SEDIMENT DWELLERS

To assess contaminant bioavailability in sediments a different type of biomonitor is required, preferably a sediment-dwelling deposit feeder that will respond to contaminant levels in freshly deposited superficial sediments.15 A substantial amount of research has been conducted on numerous benthic bivalve species, of which Scrobicularia plana and Macoma balthica are by general consent regarded as the most reliable biomonitors, not only in field monitoring studies,41,45–47 but also in laboratory bioavailability and toxicity testing studies.48–52 One major drawback with these organisms, however, is their more restricted geographical distribution compared to that of mussels and oysters, which reduces their usefulness for global monitoring programs.15 Also, as they are sediment-dwelling species, sampling is more labor-intensive.50 Another limitation was pointed out by Coelho et al.53 on the basis of the available literature on S. plana, he noted the lack of criteria homogeneity between different studies using the same species. Since each researcher often uses just one single size class,47,51 or does not even make reference to the size class studied,45,46,54 intercomparison of studies is virtually impossible. Coelho et al.53 stress the importance of having some knowledge of the lifespan and the annual bioaccumulation patterns of each species: results can then be extrapolated from one specific size class to another, and meaningful comparison between different studies becomes possible. Their study of the bioaccumulation pattern of S. plana suggested that this species accumulates mercury linearly during its lifespan and, moreover, that the ratio of annual bioaccumulation rates to the levels of this contaminant in suspended particulate matter (SPM) is consistent. If confirmed, this could prove to be a good predictor of accumulation rates for S. plana (Table 6.1). Since the bioaccumulation of mercury appears to follow a linear model, its annual accumulation rates could be predicted for any given size class, and study comparison would then be feasible.53 Polychaetes, which are generally deposit-feeding detritivores, are another group frequently considered for sediment biomonitoring purposes. The genus Hediste has been widely used,55–61 especially the species Hediste diversicolor. Some caution is necessary in their use, however, since the taxonomy of polychaetes is complex, and the coexistence of related species is common. Moreover, H. diversicolor is known to regulate the tissue concentrations of several trace elements;15 it also exhibits a wide range of feeding strategies,62 which may prevent a correct assessment of the source

TABLE 6.1 Mercury Concentrations in SPM (mg kg-1, Mean Values ± Standard Deviation), Annual Bioaccumulation Rates in S. plana (Calculated from the Slope of Regression Lines, mg kg -1 y -1), and the Ratio between Annual Accumulation Rates and SPM Hg Concentrations Station

SPM [Hg] (mg kg -1)

Annual Bioaccumulation Rates

Accumulation Rate/SPM

A1

25.8 ± 0.4

0.258

0.01

A2

20.1 ± 2.6

0.254

0.013

A4

6.5 ± 0.2

0.064

0.01

A5

8.9 ± 0.5

0.035

0.004

A11

1.0 ± 0.1

0.009

0.009

A15

1.2 ± 0.5

- 0.002

- 0.002

Source: After Coelho et al. 2006. Estuar. Coast. Shelf Sci. 69: 629–635. With permission.

108

Analytical Measurements in Aquatic Environments H. diversicolor

(a)

S. plana

0.25

[Hg]total (mg kg–1y–1)

0.2

0.15

0.1

0.05

0 A1

A2

A3

A4

A5

A6

A7

A8

A9 A10 A11 A12 A13 A14 A15

(b) 60

[Hg]org fraction (%)

50 40 30 20 10 0 A1

A2

A3

A4

A5

A6

A7

A10

A11

A12

A14

A15

Sampling stations

FIGURE 6.2 (a) Annual mercury accumulation (mg kg-1 y -1) and (b) organic mercury fraction (%) in S. plana and H. diversicolor. (After Coelho et al. 2008. Estuar. Coast. Shelf Sci. 78: 516–523. With permission.)

and extent of contamination. In a recent comparative study on mercury accumulation by H. diversicolor and S. plana, Coelho et al.61 found that the clam accumulated more mercury than the worm, both on an absolute and on an annual level, which may indicate regulation of mercury uptake by the polychaete (Figure 6.2a). In the same study, the organic mercury fraction of H. diversicolor was found to be consistently higher than that of S. plana (Figure 6.2b), and the worm’s omnivore diet was considered at least partially responsible for these results. Therefore, the use of tellinid bivalves for sediment biomonitoring seems preferable to that of polychaete worms.

6.2.4

PELAGIC SPECIES

An extensive literature exists on contaminant accumulation in fish with a wide range of dietary strategies.63–68

Biota Analysis as a Source of Information on the State of Aquatic Environments

109

The major limitation associated with the use of pelagic species for monitoring, particularly in field surveys, is the increased mobility of these larger organisms when compared to species normally used as biomonitors, that is, bivalves. Especially in point source contamination situations, there is no certainty whether organisms have been subject to the same level of contamination and for the same time periods, as would be in the case of sessile species.65,69 As tidal and seasonal migrations within aquatic systems are common,63,65 increased bias may result; this implies that fish may not accurately reflect environmental contamination at the site of collection. A solution to minimize this limitation could be to focus on immature individuals, which commonly have a restricted geographical range and would thus better reflect local contaminant stress. However, such an approach calls for caution, since other sources of uncertainty may emerge from the use of juveniles, such as dietary changes with growth. Transplantation experiments involving the caging of individuals could also cope with this limitation, although in these situations the risk of stress-related bias is not negligible. Nonetheless, the use of pelagic species to monitor aquatic environments is not without its merits. Two main goals are usually pursued when analyzing fish contaminant loads: the determination of the health risk to humans and the use of fish as environmental indicators of aquatic ecosystem quality.70 Not surprisingly, since fish are a major part of the human diet, most research focuses on the health perspective and selects edible species, as contaminants are mostly quantified in muscular tissue.64,67 This anthropocentric perspective assesses mainly the risks associated with consumption of fish70–72 and does not provide a great deal of environmental information. In contrast, studies directed toward lifespan accumulation patterns and dietary effects of accumulation66,73 may supply invaluable information on the bioaccumulation, biomagnification, and toxicity of contaminants within aquatic food webs. Given the high trophic position of fish, piscivorous species in particular may reflect the contamination and toxicity risks to top predators with diets similar to those of aquatic mammals and birds.

6.3 ASSESSMENT STRATEGIES The choice of assessment strategy will depend mainly on the purpose of the study. Most monitoring programs rely on whole-body contaminant analysis as a preferential methodology. It is especially effective for simple structured, homogenous organisms such as algae, and also small invertebrates. Sample preparation and manipulation is minimal, reducing contamination hazards, and is cost effective, given the rather unspecific nature of the process. Mussel Watch programs worldwide36–39 have used this methodology to monitor temporal trends in contaminant bioavailability since 1986.34 However, while whole-body analysis can provide information about contaminant bioavailability and bioaccumulation patterns, the origin and pathways of such accumulation are not always easy to infer. Since organisms may accumulate contaminants from water, sediments, or diet,15,17,18 studying their distribution and accumulation within organisms may provide an insight to specific bioaccumulation pathways. This information is essential for understanding the relative contribution of the various environmental compartments in accumulation and toxicity processes as well as for defining appropriate quality guidelines for water and sediments.17 A disadvantage of this kind of approach, however, is the multiplication of samples for each organ selected for analysis, involving more laboratory hours and costs for biomonitoring programs. In addition, the reduction of sample mass may prevent the use of individual organisms and impose the need to use composite samples, which will somewhat impair data interpretation. Lastly, dissection and tissue separation require expert skills to avoid sample contamination, which when working with small organisms will represent an increased risk.41 Several studies have focused on clarifying the pathways of contaminant uptake.17,74–76 These will depend not only on the specific aspects of a contaminant, but will also be species-specific and influenced by environmental variables; interpretational difficulties will inevitably ensue. For this reason, laboratory assays under controlled conditions are commonly used to assess the relative importance of each pathway in the overall contaminant accumulation in aquatic biota, and also the effect of altering environmental variables. Such studies can prove to be useful tools not only when

110

Analytical Measurements in Aquatic Environments

interpreting field data, but also when choosing species to use for monitoring specific contaminants or compartments.

6.3.1

ACCUMULATION AND PARTITIONING OF CONTAMINANTS IN PLANTS

The use of macrophytes, that is, macroalgae, sea grasses, and salt marsh plant species, to monitor the environmental quality of aquatic environments has been discussed widely, and in general, research in this area follows a similar strategy: contaminant loads are analyzed in different organs or tissues of the plant and in the surrounding environment.29,31,33,77,78 The calculation of the concentration factors (CF = [M]plant/[M]environment, in which M is the metal concentration) allows the determination of the quantitative proportions in which a given metal occurs in a macrophyte tissue or organ and in the surrounding environment. While macroalgae absorb nutrients and contaminants from the dissolved fraction, salt marsh plants incorporate them primarily through the root system, and some sea grasses through a combination of both processes. Most plants restrict the translocation of contaminants to photosynthetic tissues, accumulating them mainly in the underground biomass30,32; this makes plant roots candidates for sediment monitoring purposes. Still, some authors have also observed consistent ratios between the metal concentration in the photosynthetic tissues of sea grasses and that in the sediment (biosediment factor).28 This implies that different species demonstrate contrasting accumulation and translocation patterns (species-specific behavior) and that different contaminants will be accumulated differently within the same species;29,31,33,77,79 the choice of biomonitor therefore requires caution. Some studies have reported seasonally dependent variations in metal concentrations in macrophytes.29,77,80 Thus, a plant’s annual cycle should also be taken into account, since during the growing season, the metals may be subject to a dilution effect. In addition, there may be spatial variation within and between systems in the distribution of pollutants as a consequence of the physical and chemical characteristics of the environment (e.g., hydrology, sedimentation rates, sediment composition, temperature, salinity, and pH). Differential metal concentrations in tissues or organs, as well as the growth rates and production of sea grasses78 and salt marsh plants,81 have been used to calculate the potential cycling/turnover of metals within a system and/or the annual export of contaminants from an estuarine environment to adjacent coastal waters. Similar studies have been performed for macroalgae23 and have provided valuable information on contaminant transport and bioavailability processes within and between aquatic ecosystems, since contaminants associated with decaying plant biomasses will become bioavailable through herbivory or the detritivore food web. One final advantage associated with analyzing contaminant levels in different tissues or organs of aquatic plants is linked with the ongoing search for plant species suitable for phytoremediation/ phytoextraction, which aims to remove pollutants from the environment by repeatedly harvesting the plant biomass,14,82 and phytostabilization, the purpose of which is to restrict the bioavailability of metals in that the plant’s roots, by accumulating metals, become effective sinks.77,83 A strong candidate for phytoremediation should be a hyperaccumulator of pollutants in its aboveground biomass, that is, a plant capable of removing significant amounts of contaminant from the environment.84 Separate analyses of the different tissues or organs will therefore be essential in the search for plants appropriate to restoration efforts.84

6.3.2

DIFFERENTIAL TISSUE ANALYSIS IN ANIMALS

Differential tissue analysis is not frequent in studies involving small invertebrates, such as bivalves, polychaetes, and gastropods, since, as discussed earlier, their diminutive size poses challenging methodological problems. Nonetheless, examples of the usefulness of this approach can be found in the literature. One study compared the specific tissue distribution of cadmium and two forms of mercury in the clam Corbicula fluminea when exposed to contaminated water or sediments;85 the metal distributions in five selected organs were reported to display strong specificities, in accordance

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with their different contamination modalities. In a study on two other bivalve species, the spiny and Pacific scallops, specific tissue analysis enabled Nørum et al.86 to assess the effects of species, gender, and reproductive state on the differential accumulation of several metals. On the basis of these findings, the authors were able to suggest some strategies for improving biomonitoring programs, such as gender separation or equal/constant sex composition when using pooled samples. For a large number of contaminants, however, most research has made use of larger organisms, mainly decapod crustaceans,87–90 cephalopods,74 and fish.75,76,91 Despite mobility being referred as a source of bias in a field study on the pattern and pathways of mercury lifespan bioaccumulation in Carcinus maenas90 (Figure 6.3), the use of differential tissue analysis still managed to discriminate two different pathways for the accumulation of this metal. In areas of low contamination, diet was considered to be the main source of mercury; this was reflected by higher levels in the internal organs (muscle and hepatopancreas) than in the gills, and higher organic mercury fractions (80–90%) in muscle tissue, suggesting uptake from organic mercury-rich dietary items. In highly contaminated areas, however, environmental exposure was found to be predominant, with lower organic fractions in all tissues and higher concentrations in gills. Similar findings had previously been reported by Laporte et al.,87 who stated that mercury accumulation in the gills was associated with a higher intake of inorganic mercury, as the gills are in contact mostly with the dissolved and particulate species in water. The same arguments are valid for the widespread tissue discrimination in fish contaminant analyses. Alquezar et al.75,76 used a similar approach to assess metal accumulation and uptake pathways in the tissues of Tetractenos glaber, and also noticed gender differential accumulation. Studies involving fish, however, are usually approached from a rather anthropocentric standpoint, given that in general only edible tissues are analyzed, despite other tissues being more sensitive and indicative of contamination.

[Hg] (mg kg–1)

0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0

% [Hg]org

Gills

90 80 70 60 50 40 30 20 10 0

Hepatopancreas

High contamination

Muscle Low contamination

0.16 0.14 0.12 0.1 0.08 0.06 0.04 0.02 0 90 80 70 60 50 40 30 20 10 0

1+

2+ Females

3+

1+

2+ Males

3+

1+

2+ Females

3+

1+

2+

3+

Males

FIGURE 6.3 Mercury concentrations (mg kg-1) and organic mercury percentages in the different tissues and genders of 1+, 2+, and 3+ year old Carcinus maenas. (After Coelho et al. 2008. Mar. Pollut. Bull. 56: 1104–1110. With permission.)

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Analytical Measurements in Aquatic Environments

SUPPLEMENTARY METHODOLOGIES

Ecological or environmental risk assessment (ERA) is defined as the procedure by which the likely or actual adverse effects of pollutants and other anthropogenic activities on ecosystems and their components are estimated with a known degree of certainty using scientific methodologies.92 Despite the usefulness (extensively discussed above) of bioaccumulation markers for establishing connections between external levels of exposure and internal levels of tissue contamination, some limitations of this approach must be underlined in the light of the previous concept of ERA. Even if applied in an organ-specific perspective, bioaccumulation markers have failed with respect to hazard identification and effect assessment, since they are incapable of directly indicating the possible development of harmful effects or the actual induction of damage. To fill this gap, therefore, and thus to enhance the efficacy of monitoring programs, the assessment of adaptive responses or early adverse effects on biota is strongly recommended as a complementary tool. As a general rule, organisms have developed protective mechanisms that increase their resistance to contaminants, including metals. Biochemical in nature, these mechanisms include the induction of MTs as well as the synthesis and activation of antioxidant defenses. Therefore, as biochemical markers they play a key role, acting as early-warning signals, the detection of which can prevent adverse effects at higher hierarchical levels.93

6.4.1 OXIDATIVE STRESS There is a close relationship between environmental exposure to contaminants and the generation in the organism of intracellular reactive oxygen species (ROS), such as superoxide (O2•-) and hydroxyl (HO •) radicals, and hydrogen peroxide (H2O2). To cope with the overproduction of potentially damaging ROS, eukaryotic organisms can increase the levels of protective antioxidant enzymes— catalase (CAT), glutathione peroxidase (GPx), and superoxide dismutase (SOD)—as well as nonenzymatic free radical scavengers such as reduced glutathione (GSH). When the balance between oxidants and antioxidants is disturbed in favor of the former, the organism is considered to be in a state of “oxidative stress.” Under these conditions, reactive oxygen intermediates may damage DNA and membrane lipids, and affect the function of cellular proteins. Among a wide range of contaminant-induced molecular changes measured in aquatic species, oxidative stress [DNA damage, protein oxidation, and lipid peroxidation (LPO)] and/or antioxidant responses have been rapidly gaining recognition in recent years as a key phenomenon, being commonly employed as nonspecific biomarkers.94 In relation to metals, it is most likely that oxidative stress is a sensitive endpoint, because mitochondria, the major intracellular source of ROS, are common targets for this class of chemicals.95 Although metals are recognized as important oxidative agents in aquatic organisms from different taxa, the integrated analysis of oxidative stress (oxidative damage and antioxidant defense) parameters and metal loads in key tissues/organs has not been extensively explored under field conditions. Metal-induced oxidative stress responses have been neglected in macroalgae; the few studies that have been carried out were done under controlled laboratory conditions rather than in real field scenarios. To the authors’ knowledge, a single study is available on native seaweeds:96 A species-specific resistance to metals (As, Cu, Cd, Pb, and Zn) associated with a GSH content increase is reported in Fucus spp., Rhizoclonium tortuosum, and Ulva spp., which enabled these species to thrive in highly contaminated environments. The lack of studies on this group of organisms is probably related to the prevalent assumption that plants are less sensitive to chemicals than aquatic animal species.97 However, according to Nimptsch et al.,98 susceptibility to toxicants depends both on the species used and on the contaminants rather than on differences between plants and animals. Indigenous mussels (Mytilus galloprovincialis) of the Saronikos Gulf in Greece were used for monitoring heavy metal pollution.99 The results indicated the induction of CAT and SOD activity as

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well as an increase in LPO in the gills and mantle as a result of cellular oxyradical generation associated with metal body burdens. A similar approach was applied in biomonitoring studies using fish. Changes to the antioxidant enzymes, glutathione system, and LPO induction reflected the presence of heavy metals (Zn, Cu, Cd, As, and Pb) in different tissues of environmentally exposed Clarias gariepinus.100 In a study carried out along an estuarine area impacted by mercury discharges (Ria de Aveiro, Portugal), oxidative stress responses were assessed in fish liver and related to total mercury concentrations in Liza aurata seasonally collected and caged in the study area.101 Despite the significant increase in hepatic mercury load, no evidence of peroxidative damage was detected in wild or caged fish, an observation attributed to the effectiveness of antioxidant defenses, that is, GSH and CAT activity. Although the integrated approach adopted in the previously mentioned studies provides a more representative picture of the systems under study, there are numerous examples in the literature of studies investigating oxidative stress responses without the complementary assessment of the tissue contaminant load. The significance of such isolated analysis may be compromised by certain factors capable of confounding the interpretation of the results. For instance, false-negative results can arise from the presence of antioxidant enzyme inhibitors in the environment; in the presence of mixtures of chemicals, therefore, antioxidant responses reflect the balance between inducers and inhibitors.102 In addition, other environmental parameters unrelated to pollution, such as temperature, salinity, and oxygen, can cause important changes in these biochemical responses.103–105 Therefore, basic information about the influence of these factors on the biomarker to be used in different species is required in order to ensure accuracy of measurement.105 Summarizing, to minimize uncertainties and avoid misinterpretations, the combined approach (bioaccumulation markers/oxidative stress responses) is recommended. Moreover, this integrated approach may provide insight into the potential mechanisms of contaminant effects, so that cause– effect relationships can be established, something that is particularly relevant given the presence of complex mixtures.

6.4.2 METALLOTHIONEINS The majority of biomonitoring studies involves analyzing the bulk contaminant concentration in the whole body or selected tissues of organisms. However, many marine organisms (both vertebrate and invertebrate) possess defense mechanisms to cope with contamination, through immobilization and accumulation in specific organs, cells, or proteins;106 accumulated contaminants can then be stored, metabolized, or excreted. In view of this, the validity of bulk chemical analyses as a measure of contaminant impact and toxicity must be questioned. In the specific case of heavy metal pollution, particular attention has been given to MTs. These are heat-resistant, nonenzymatic proteins with a high cysteine content and low molecular weight, whose major function is considered to be the regulation and metabolism of essential metals such as Cu and Zn.72,107 In addition to this regulatory function, MTs are thought to play a role in metal detoxification. An excess of intracellular free metal ions, whether essential or not, can have damaging effects, impairing several vital cellular functions. Generally, MT synthesis is assumed to be induced under conditions of elevated metal concentration, providing more binding sites for metal ions and limiting possible damage. Generally, MT expression increases with the elevation of tissue concentrations of MT-inducing metals (Ag, Cd, Cu, Hg, etc.), thus reflecting metal bioavailability in the environment.108 The induction of MT is, therefore, a potentially powerful biochemical indicator of response to metal contamination.107,109 Research on the subject has encountered some inconsistencies, giving rise to a few questions that may cripple their usefulness as an environmental biomonitoring tool. In polluted environments, animals are generally exposed to a mixture of different metals, and it is generally impossible to attribute MT induction to one element or another. On the other hand, several papers have reported

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the absence of MT induction in invertebrates exposed to metals, or even a decrease in MT concentrations following exposure to metals. In a review of this theme, Amiard et al.107 raised three main issues regarding the use of MT as a biomarker of metal pollution that need clarification: its dependency on specific metals, on biological characteristics (species, population, and organ), and on the period and dose of exposure. The first issue was highlighted by Barka et al.,110 among others, who tested MT induction in the copepod Tigriopus brevicornis by a suite of metals and reported differences in the induction capacities of selected metals. Bebianno and Machado,111 on the other hand, found MT levels to correlate positively with Cd and Cu concentrations but not with Zn in Mytilus galloprovincialis. The dependency of MT induction on biological characteristics is more evident in invertebrate species, whereas in vertebrates metal detoxification is carried out mainly through binding to MTs. Metal sequestration in invertebrates occurs through various processes, such as immobilization as inorganic precipitates, and accumulation as insoluble lipofuschin pigments in tertiary lysosomes and non-MT metal-binding proteins.106,112 Differences between vertebrate and invertebrate species with regard to MT induction patterns are therefore common. Even among closely related species, such as the two decapod crustaceans Carcinus maenas and Pachygrapsus marmoratus, Legras et al.113 found significant differences in metal accumulation and MT induction, suggesting speciesspecific traits in the role of MT in metal detoxification. In the oyster Crassostrea gigas, a seasonal study114,115 demonstrated that MT concentrations in the digestive gland were only occasionally correlated with accumulated metal concentrations, whereas in the gills, such correlations were observed over the major part of the year. However, even in the gills, seasonal variations in MT concentrations were high enough to conceal intersite differences when annual means were calculated for all the individuals analyzed monthly. In considering the period and dose of exposure, Mouneyrac et al.116 reported that populations of the amphipod Orchestia gammarellus from estuaries with contrasting metal contamination failed to demonstrate differences in MT induction, since MT body concentrations did not increase upon exposure to raised availabilities of Cu, Zn, or Cd. From their findings, these authors concluded that MT-like proteins were unsuitable as potential biomarkers. In addition, a number of studies have indicated that MTs are also induced by nonmetals, for example, organic aromatic compounds.117,118 This has raised doubts regarding the use of this parameter as a specific biomarker for metal exposure. Despite all these inconsistencies and uncertainties, however, MT induction is a valuable methodology, although not alone but as part of a suite of biomonitoring strategies, provided that caution is exercised and the experimental design optimized. The choice of species is crucial: While some authors106 recommend the use of fish in view of the various competing mechanisms of metal sequestration in invertebrates, the excessive mobility of such pelagic species is a major limitation. Bivalves are therefore most probably the best candidates for biomonitoring programs involving MT concentrations as biomarkers,107 for the same reasons that made them ideal as contaminant load biomonitors. The same authors also emphasize the importance of making a good choice of organ in which to measure MT concentrations when these proteins are used as a biomarker, since protein induction is usually stronger in the gills and digestive glands. Finally, confounding factors such as salinity,119 seasonality,112,115 sex and reproductive state,113,120 and size72 should be taken into account and efforts made to minimize the associated bias. A very similar approach using primary producers is based on an analogous defense mechanism— the production of PCs. In the presence of excess metals, PCs are formed, which effectively capture metals. A major advantage of PCs over MTs is their specificity for metals, since no other environmental factors are known to induce PC accumulation; the activation of PCs is considered to ensue from a direct “sensing” of metal excess.121 An elevated PC level in macroalgae and sea grasses has also been used as a specific biomarker of heavy metal bioavailability and stress.122 PCs do indeed seem to be representative of the level of perturbation of the medium and of the health of the organisms, and they could therefore be used for the early detection of changes in water quality.122

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115

CONCLUSIONS

In a general perspective, the use of biota as a source of environmental information provides invaluable data on the health status of aquatic ecosystems, with numerous advantages over sediment or dissolved contaminant analyses. Biomonitoring programs and scientific research must rely on careful experimental designs, in which three main issues should be addressed: Firstly, the meticulous selection of species to monitor, which will depend on the desired environmental compartments to be assessed and the target contaminant. No universal biomonitor exists, hence a suite of species is advisable, each reflecting specific trophic levels and thus different compartments of the ecosystem. Secondly, the assessment strategy should be adjusted according to the selected species, since tissue discrimination will provide additional information on accumulation pathways and specific toxicity mechanisms; but this procedure is more labor-intensive and time-consuming, not to mention the difficulties associated with sampling mass in smaller organisms. Finally, the use of biomarkers such as oxidative stress indicators or MT induction may provide useful, quantitative information on the effects of contaminants, given that whole-body analyses fail to indicate what portion of the contaminant body burden is actually reactive and thus responsible for adverse effects in biota.

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41. De Kock, W.C. and K.J.M. Kramer. 1994. Active biomonitoring (ABM) by translocation of bivalve molluscs. In: K.J.M. Kramer (ed.), Biomonitoring of Coastal Waters and Estuaries, pp. 51–85. Boca Raton, FL: CRC Press. 42. Mikac, N., Z. Kwokal, D. Martincic, and M. Branica, 1996. Uptake of mercury species by transplanted mussels Mytilus galloprovincialis under estuarine conditions (Krka river estuary). Sci. Total Environ. 184: 173–182. 43. Abbe, G.R., G.F. Riedel, and J.G. Sanders. 2000. Factors that influence the accumulation of copper and cadmium by transplanted eastern oysters (Crassostrea virginica) in the Patuxent River, Maryland. Mar. Environ. Res. 49: 377–396. 44. Olivier, F., M. Ridd, and D. Klumpp. 2002. The use of transplanted cultured tropical oysters (Saccostrea commercialis) to monitor Cd levels in North Queensland coastal waters (Australia). Mar. Pollut. Bull. 44: 1051–1062. 45. Ruiz, J.M. and J.I. Saiz-Salinas. 2000. Extreme variation in the concentration of trace metals in sediments and bivalves from the Bilbao estuary (Spain) caused by the 1989–90 drought. Mar. Environ. Res. 49: 307–317. 46. Ridgway, J., N. Breward, W.J. Langston, R. Lister, J.G. Rees, and S.M. Rowlatt. 2003. Distinguishing between natural and anthropogenic sources of metals entering the Irish Sea. Appl. Geochem. 18: 283–309. 47. Cheggour, M., A. Chafik, N.S. Fisher, and S. Benbrahim. 2005. Metal concentrations in sediments and clams in four Moroccan estuaries. Mar. Environ. Res. 59: 119–137. 48. Boisson, F., M.G.J. Hartl, S.W. Fowler, and C. Amiard-Triquet. 1998. Influence of chronic exposure to silver and mercury in the field on the bioaccumulation potential of the bivalve Macoma balthica. Mar. Environ. Res. 45: 325–340. 49. Stecko, J.R.P. and L.I. Bendell-Young. 2000. Uptake of 109Cd from sediments by the bivalves Macoma balthica and Protothaca staminea. Aquat. Toxicol. 47: 147–159. 50. Byrne, P.A. and J. O’Halloran. 2001. The role of bivalve molluscs as tools in estuarine sediment toxicity testing: A review. Hydrobiologia 465: 209–217. 51. García-Luque, E., T.A. Delvalls, C. Casado-Martínez, J.M. Forja, and A. Gómez-Parra. 2004. Simulating a heavy metal spill under estuarine conditions: Effects on the clam Scrobicularia plana. Mar. Environ. Res. 58: 671–674. 52. Riba, I., M.C. Casado-Martínez, J. Blasco, and T.A. Delvalls. 2004. Bioavailability of heavy metals bound to sediments affected by a mining spill using Solea senegalensis and Scrobicularia plana. Mar. Environ. Res. 58: 395–399. 53. Coelho, J.P., M. Rosa, E. Pereira, A. Duarte, and M.A. Pardal. 2006. Pattern and annual rates of Scrobicularia plana mercury bioaccumulation in a human induced mercury gradient (Ria de Aveiro, Portugal). Estuar. Coast. Shelf Sci. 69: 629–635. 54. Pérez, E., J. Blasco, and M. Solé. 2004. Biomarker responses to pollution in two invertebrate species: Scrobicularia plana and Nereis diversicolor from the Cádiz Bay (SW Spain). Mar. Environ. Res. 58: 275–279. 55. Hylland, K., M. Sköld, J.S. Gunnarsson, and J. Skei. 1997. Interactions between Eutrophication and contaminants. IV. Effects on sediment-dwelling organisms. Mar. Pollut. Bull. 33: 90–99. 56. Muhaya, B.B.M., M. Leermakers, and W. Baeyens. 1997. Total mercury and methylmercury in sediments and in the polychaete Nereis diversicolor at Groot Buitenschoor (Scheldt estuary, Belgium). Water Air Soil Pollut. 94: 109–123. 57. Baeyens, W., C. Meuleman, B. Muhaya, and M. Leermakers. 1998. Behaviour and speciation of mercury in the Scheldt estuary (water, sediments and benthic organisms). Hydrobiologia 366: 63–79. 58. Bernds, D., D. Wübben, and G.-P. Zauke. 1998. Bioaccumulation of trace metals in polychaetes from the German Wadden Sea: Evaluation and verification of toxicokinetic models. Chemosphere 37: 2573–2587. 59. Ruus, A., M. Schaanning, S. Øxnevad, and K. Hylland. 2005. Experimental results on bioaccumulation of metals and organic contaminants from marine sediments. Aquat. Toxicol. 72: 273–292. 60. Durou, C., L. Poirier, J.-C. Amiard, et al. 2007. Biomonitoring in a clean and a multi-contaminated estuary based on biomarkers and chemical analyses in the endobenthic worm Nereis diversicolor. Environ. Pollut. 148: 445–458. 61. Coelho, J.P., M. Nunes, M. Dolbeth, M.E. Pereira, A.C. Duarte and M.A. Pardal. 2008. The role of two sediment dwelling invertebrates on the mercury transfer from sediments to the estuarine trophic web. Estuar. Coast. Shelf Sci. 78: 516–523. 62. Scaps, P. 2002. A review of the biology, ecology and potential use of the common ragworm Hediste diversicolor (O.F. Müller) (Annelida: Polychaeta). Hydrobiologia 470: 203–218.

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63. Abreu, S.N., E. Pereira, C. Vale, and A.C. Duarte, 2000. Accumulation of mercury in sea bass from a contaminated lagoon (Ria de Aveiro, Portugal). Mar. Pollut. Bull. 40: 293–297. 64. Alonso, D., P. Pineda, J. Olivero, H. González, and N. Campos, 2000. Mercury levels in muscle of two fish species and sediments from the Cartagena Bay and the Ciénaga Grande de Santa Marta, Colombia. Environ. Pollut. 109: 157–163. 65. Usero, J., C. Izquierdo, J. Morillo, and I. Gracia. 2003. Heavy metals in fish (Solea vulgaris, Anguilla anguilla and Liza aurata) from salt marshes on the southern Atlantic coast of Spain. Environ. Int. 29: 949–956. 66. Henry, F., R. Amara, L. Courcot, D. Lacouture, and M.-L. Bertho. 2004. Heavy metals in four fish species from the French coast of the Eastern English Channel and Southern Bight of the North Sea. Environ. Int. 30: 675–683. 67. Marcovecchio, J.E. 2004. The use of Micropogonias furnieri and Mugil liza as bioindicators of heavy metals pollution in La Plata river estuary, Argentina. Sci. Total Environ. 323: 219–226. 68. Meador, J.P., D.W. Ernest, and A.N. Kagley. 2005. A comparison of the non-essential elements cadmium, mercury, and lead found in fish and sediment from Alaska and California. Sci. Total Environ. 339: 189–205. 69. Pereira, M.E., S.N. Abreu, J.P. Coelho, et al. 2006. Seasonal fluctuations of tissue mercury contents in the European shore crab Carcinus maenas from low and high contamination areas (Ria de Aveiro, Portugal). Mar. Pollut. Bull. 52: 1450–1457. 70. Davis, J.A., M.D. May, B.K. Greenfield, et al. 2002. Contaminant concentrations in sport fish from San Francisco Bay, 1997. Mar. Pollut. Bull. 44: 1117–1129. 71. Kehrig, H.A., O. Malm, and I. Moreira. 1998. Mercury in a widely consumed fish Micropogonias furnieri (Demarest, 1823) from four main Brazilian estuaries. Sci. Total Environ. 213: 263–271. 72. Bebianno, M.J., C. Santos, J. Canário, N. Gouveia, D. Sena-Carvalho, and C. Vale. 2007. Hg and metallothionein-like proteins in the black scabbardfish Aphanopus carbo. Food Chem. Toxicol. 45: 1443–1452. 73. Penedo de Pinho, A., J.R.D. Guimarães, A.S. Martins, P.A.S. Costa, G. Olavo, and J. Valentin. 2002. Total mercury in muscle tissue of five shark species from Brazilian offshore waters: Effects of feeding habit, sex, and length. Environ. Res. Section A 89: 250–258. 74. Danis, B., P. Bustamante, O. Cotret, J.L. Teyssié, S.W. Fowler, and M. Warnau. 2005. Bioaccumulation of PCBs in the cuttlefish Sepia officinalis from seawater, sediment and food pathways. Environ. Pollut. 134: 113–122. 75. Alquezar, R., S.J. Markich, and D.J. Booth. 2006. Metal accumulation in the smooth toadfish, Tetractenos glaber, in estuaries around Sydney, Australia. Environ. Pollut. 142: 123–131. 76. Alquezar, R., S.J. Markich, and J.R. Twining. 2008. Comparative accumulation of 109Cd and 75Se from water and food by an estuarine fish (Tetractenos glaber). J. Environ. Radioact. 99: 167–180. 77. Almeida, C.M.R., A.P. Mucha, and M.T.S.D. Vasconcelos. 2006. Comparison of the role of the sea clubrush Scirpus maritimus and the sea rush Juncus maritimus in terms of concentration, speciation and bioaccumulation of metals in the estuarine sediment. Environ. Pollut. 142: 151–159. 78. Kaldy, J.E. 2006. Carbon, nitrogen, phosphorus and heavy metal budgets: How large is the eelgrass (Zostera marina L.) sink in a temperate estuary? Mar. Pollut. Bull. 52: 332–356. 79. Sousa A.I., I. Caçador, A.I. Lillebø, and M. Pardal. 2008. Heavy metal accumulation in Halimione portulacoides: Intra- and extra-cellular metal binding sites. Chemosphere 70: 850–857. 80. Z˙bikowski, R., P. Szefer, and A. Latała. 2006. Distribution and relationships between selected chemical elements in green alga Enteromorpha sp. from the southern Baltic. Environ. Pollut. 143: 435–448. 81. Válega, M., A.I. Lillebø, I. Caçador, M.E. Pereira, A.C. Duarte, and M.A Pardal. 2008. Mercury mobility in a salt marsh colonised by Halimione portulacoides. Chemosphere 73: 1224–1229. 82. Riddle, S.G., H.H. Tran, J.G. Dewitt, and J.C. Andrews. 2002. Field, laboratory, and X-ray absorption spectroscopic studies of mercury accumulation by water hyacinths. Environ. Sci. Technol. 36: 1965–1970. 83. Reboreda, R. and I. Caçador. 2007. Halophyte vegetation influences in salt marsh retention capacity for heavy metals. Environ. Pollut. 146: 147–154. 84. Weis, J.S. and P. Weis. 2004. Metal uptake, transport and release by wetland plants: Implications for phytoremediation and restoration. Environ. Int. 30: 685–700. 85. Inza, B., F. Ribeyre, R. Maury-Brachet, and A. Boudou. 1997. Tissue distribution of inorganic mercury, methylmercury and cadmium in the Asiatic clam (Corbicula fluminea) in relation to the contamination levels of the water column and sediment. Chemosphere 35: 2817–2836. 86. Nørum, U., V.W.-M. Lai, and W.R. Cullen. 2005. Trace element distribution during the reproductive cycle of female and male spiny and Pacific scallops, with implications for biomonitoring. Mar. Pollut. Bull. 50: 175–184.

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87. Laporte, J.M., F. Ribeyre, J.P. Truchot, and A. Boudou. 1997. Combined effects of water pH and salinity on the bioaccumulation of inorganic mercury and methylmercury in the shore crab Carcinus maenas. Mar. Pollut. Bull. 34: 880–893. 88. Laporte, J.M., S. Andres, and R.P. Mason. 2002. Effect of ligands and other metals on the uptake of mercury and methylmercury across the gills and the intestine of the blue crab (Callinectes sapidus). Comp. Biochem. Physiol. Part C 131: 185–196. 89. Bodin, N., A. Abarnou, A.-M. Le Guellec, V. Loizeau, and X. Philippon. 2007. Organochlorinated contaminants in decapod crustaceans from the coasts of Brittany and Normandy (France). Chemosphere 67: S36–S47. 90. Coelho, J.P., A.T. Reis, S. Ventura, M.E. Pereira, A.C. Duarte, and M.A. Pardal. 2008. Pattern and pathways for mercury lifespan bioaccumulation in Carcinus maenas. Mar. Pollut. Bull. 56: 1104–1110. 91. Klinck, J.S., W.W. Green, R.S. Mirza, et al. 2007. Branchial cadmium and copper binding and intestinal cadmium uptake in wild yellow perch (Perca flavescens) from clean and metal-contaminated lakes. Aquat. Toxicol. 84: 198–207. 92. Depledge, M.H. and M.C. Fossi. 1994. The role of biomarkers in environmental assessment (2). Ecotoxicology 3: 161–172. 93. van der Oost, R., J. Beyer, and N.P.E. Vermeulen. 2003. Fish bioaccumulation and biomarkers in environmental risk assessment: A review. Environ. Toxicol. Pharmacol. 13: 57–149. 94. Monterroso, P., S.N. Abreu, E. Pereira, C. Vale, and A.C. Duarte. 2003. Estimation of Cu, Cd and Hg transported by plankton from a contaminated area (Ria de Aveiro). Acta Oecol. 24: S351–S357. 95. Wang, G. and B.A. Fowler. 2008. Roles of biomarkers in evaluating interactions among mixtures of lead, cadmium and arsenic. Toxicol. Appl. Pharmacol. 233: 92–99. 96. Pawlik-Skowron´ska, B., J. Pirszel, and M.T. Brown. 2007. Concentrations of phytochelatins and glutathione found in natural assemblages of seaweeds depend on species and metal concentrations of the habitat. Aquat. Toxicol. 83: 190–199. 97. Mohan, B.S. and B.B. Hosetti. 1999. Review: Aquatic plants for toxicity assessment. Environ. Res. Section A 81: 259–274. 98. Nimptsch, J., D.A. Wunderlin, A. Dollar, and S. Pflugmacher. 2005. Antioxidant and biotransformation enzymes in Myriophyllum quitense as biomarkers of heavy metal exposure and eutrophication in Suquía River basin (Córdoba, Argentina). Chemosphere 61: 147–157. 99. Vlahogianni, T., M. Dassenakis, M.J. Scoullos, and A. Valavanidis. 2007. Integrated use of biomarkers (superoxide dismutase, catalase and lipid peroxidation) in mussels Mytilus galloprovincialis for assessing heavy metals’ pollution in coastal areas from the Saronikos Gulf of Greece. Mar. Pollut. Bull. 54: 1361–1371. 100. Farombi, E.O., O.A. Adelowo, and Y.R. Ajimoko. 2007. Biomarkers of oxidative stress and heavy metal levels as indicators of environmental pollution in African cat fish (Clarias gariepinus) from Nigeria Ogun River. Int. J. Environ. Res. Public Health 4: 158–165. 101. Guilherme, S., M. Válega, M.E. Pereira, M.A. Santos, and M. Pacheco. 2008. Antioxidant and biotransformation responses in Liza aurata under environmental mercury exposure—relationship with mercury accumulation and implications for public health. Mar. Pollut. Bull. 56: 845–859. 102. Ahmad, I., M. Pacheco, and M.A. Santos. 2006. Anguilla anguilla L. oxidative stress biomarkers: An in situ study of freshwater wetland ecosystem (Pateira de Fermentelos, Portugal). Chemosphere 65: 952–962. 103. Malek, R.L., H. Sajadi, J. Abraham, M.A. Grundy, and G.S. Gerhard. 2004. The effects of temperature reduction on gene expression and oxidative stress in skeletal muscle from adult zebra fish. Comp. Biochem. Physiol. Part C 138: 363–373. 104. Olsvik, P.A., T. Kristensen, R. Waagbo, K.E. Tollefsen, B.O. Rosseland, and H. Toften. 2006. Effects of hypo- and hyperoxia on transcription levels of five stress genes and the glutathione system in liver of Atlantic cod Gadus morhua. J. Exp. Biol. 209: 2893–2901. 105. Almeida, E.A., C.D. Bainy, A.P. Loureiro, et al. 2007. Oxidative stress in Perna perna and other bivalves as indicators of environmental stress in the Brazilian marine environment: Antioxidants, lipid peroxidation and DNA damage. Comp. Biochem. Physiol. Part A 146: 588–600. 106. George, S.G. and P.-E. Olsson. 1994. Metallothioneins as indicators of trace metal pollution. In: K.J.M. Kramer (ed.), Biomonitoring of Coastal Waters and Estuaries, pp. 151–179. Boca Raton, FL: CRC Press. 107. Amiard, J.-C., C. Amiard-Triquet, S. Barka, J. Pellerin, and P.S. Rainbow. 2006. Metallothioneins in aquatic invertebrates: Their role in metal detoxification and their use as biomarkers. Aquat. Toxicol. 76: 160–202.

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108. Monserrat, J.M., P.E. Martínez, L.A. Geracitano, et al. 2007. Pollution biomarkers in estuarine animals: Critical review and new perspectives. Comp. Biochem. Physiol. Part C 146: 221–234. 109. Langston, W.S., B.S. Chesman, G.R. Burt, N.D. Pope, and J. McEvoy. 2002. Metallothionein in liver of eels Anguilla anguilla from the Thames Estuary: An indicator of environmental quality? Mar. Environ. Res. 53: 263–293. 110. Barka, S., J.-F. Pavillon, and J.-C. Amiard. 2001. Influence of different essential and non-essential metals on MTLP levels in the Copepod Tigriopus brevicornis. Comp. Biochem. Physiol. Part C 128: 479–493. 111. Bebianno, M.J. and L.M. Machado. 1997. Concentrations of metals and metallothioneins in Mytilus galloprovincialis along the South Coast of Portugal. Mar. Pollut. Bull. 34: 666–671. 112. Geffard, A., C. Amiard-Triquet, and J.-C. Amiard. 2005. Do seasonal changes affect metallothionein induction by metals in mussels, Mytilus edulis? Ecotoxicol. Environ. Saf. 61: 209–220. 113. Legras, S., S. Mouneyrac, J.-C. Amiard, C. Amiard-Triquet, and P.S. Rainbow. 2000. Changes in metallothionein concentrations in response to variation in natural factors (salinity, sex, weight) and metal contamination in crabs from a metal-rich estuary. J. Exp. Mar. Biol. Ecol. 246: 259–279. 114. Geffard, A., C. Amiard-Triquet, J.-C. Amiard, and C. Mouneyrac. 2001. Temporal variations of metallothionein and metal concentrations in the digestive gland of oysters (Crassostrea gigas) from a clean and a metal-rich site. Biomarkers 6: 91–107. 115. Geffard, A., J.C. Amiard, and C. Amiard-Triquet. 2002. Use of metallothionein in gills from oysters (Crassostrea gigas) as a biomarker: Seasonal and intersite fluctuations. Biomarkers 7: 123–137. 116. Mouneyrac, C., J.C. Amiard, C. Amiard-Triquet, A. Cottier, P.S. Rainbow, and B.D. Smith. 2002. Partitioning of accumulated trace metals in the talitrid amphipod crustacean Orchestia gammarellus: A cautionary tale on the use of metallothionein-like proteins as biomarkers. Aquat. Toxicol. 57: 225–242. 117. Pedrajas, J.R., J. Peinado, and J. LopezBarea. 1995. Oxidative stress in fish exposed to model xenobiotics. Oxidatively modified forms of Cu, Zn superoxide dismutase as potential biomarkers. Chem. Biol. Interact. 98: 267–282. 118. Kling, P., L.J. Erkell, P. Kille, and P.E. Olsson. 1996. Metallothionein induction in rainbow trout gonadal (RTG-2) cells during free radical exposure. Mar. Environ. Res. 42: 33–36. 119. Leung, K.M.Y., J. Svavarsson, M. Crane, and D. Morritt. 2002. Influence of static and fluctuating salinity on cadmium uptake and metallothionein expression by the dogwhelk Nucella lapillus (L.). J. Exp. Biol. Ecol. 274: 175–189. 120. Mouneyrac, C., C. Amiard-Triquet, J.C. Amiard, and P.S. Rainbow. 2001. Comparison of metallothionein concentrations and tissue distribution of trace metals in crabs (Pachygrapsus marmoratus) from a metalrich estuary, in and out of the reproductive season. Comp. Biochem. Physiol. Part C 129: 193–209. 121. Clemens, S. 2006. Toxic metal accumulation, responses to exposure and mechanisms of tolerance in plants. Biochimie 88: 1707–1719. 122. Ferrat L., C. Pergent-Martini, and M. Roméo. 2003. Assessment of the use of biomarkers in aquatic plants for the evaluation of environmental quality: Application to sea grasses. Aquat. Toxicol. 65: 187–204.

7

Speciation Analytics in Aquatic Ecosystems A. de Brauwere, Y. Gao, S. De Galan, W. Baeyens, M. Elskens, and M. Leermakers

CONTENTS 7.1 7.2

Introduction ...................................................................................................................... Speciation of Dissolved Cr, Fe, Mn, and As ..................................................................... 7.2.1 In Situ Speciation in the Aquatic System ............................................................. 7.2.2 Sampling ............................................................................................................... 7.2.3 Sample Preservation and Storage ......................................................................... 7.2.4 Electrochemical Speciation .................................................................................. 7.2.5 Hyphenated Methods ............................................................................................ 7.2.5.1 Exchange Columns (Trap and Elute) ..................................................... 7.2.5.2 Chromatography .................................................................................... 7.2.5.3 Chemiluminescence and Colorimetric Reactions .................................. 7.2.6 Other Methods ...................................................................................................... 7.3 Speciation of Dissolved Hg ............................................................................................... 7.3.1 Sample Handling and Storage .............................................................................. 7.3.2 Analytical Methods for Hg(0), DMHg, Hg-R, and Hg-T ...................................... 7.3.3 Analytical Methods for MMHg ............................................................................ 7.3.3.1 Extraction Procedures ............................................................................ 7.3.3.2 Gas Chromatographic Separation Methods ........................................... 7.3.3.3 Derivatization and Validation ................................................................ 7.3.3.4 GC Improvements .................................................................................. 7.3.3.5 Liquid Chromatographic Separation Methods ...................................... 7.3.3.6 Detection Methods ................................................................................. 7.3.4 Speciation Modeling of Hg ................................................................................... Acknowledgment ....................................................................................................................... References ..................................................................................................................................

7.1

121 122 123 125 126 126 127 127 127 128 128 129 129 130 130 130 130 130 131 131 132 132 132 132

INTRODUCTION

The speciation of redox-sensitive elements (e.g., Cr, Fe, and Mn), redox-sensitive elements that also form organometallic compounds (e.g., As), and redox-sensitive elements that also form organometallic and volatile compounds (e.g., Hg) in aquatic systems is discussed in this chapter. Because the scope of this subject is so large, only the dissolved phase in the aquatic system will be considered. There are many reasons why chemists are not satisfied with the assessment of total trace metal levels in aquatic systems, but want to go further and gather information about the speciation of these metals. There are, for example, differences in toxicity [e.g., Cr(III) versus Cr(VI), As(III) versus 121

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TABLE 7.1 Concentration Levels of Trace Metal Species in Various Aquatic Systems Species

Groundwater 1,2,3

Cr-T Fe-T Mn-T As-T

0.20–67 nM 0.60–180 μM5 21–25 μM1 0.13–1.33 nM (unpolluted)11 1.30–67 μM (polluted)11

Hg-T Hg-R Hg(0) MMHg

River or Lake Water

Coastal Water

4

0.50–100 nM 4–120 μM6,7 0.050–18 μM6,9 0.15 μM (mean) Up to 1.70 μM12 0.40–16 pM13 0.50–10 pM13 0.10–0.67 pM13 0.050–3 pM13

Open Seawater

5–400 nM 0.10–49 μM7

0.10–16 nM4 0.050–2 nM8 0.50–3 nM10 0.13–0.27 nM11

0.60–7.1 pM13 0.40–1.8 pM13 0.10–0.80 pM13 0.075–0.94 pM13

0.70–2.0 pM13 0.05–0.89 pM13

8

As(V), and Hg(II) versus MMHg (monomethyl-Hg)], solubility [e.g., Fe(II) versus Fe(III) and Mn(II) versus Mn(IV)], the difference in volatility [Hg(0) versus Hg(II)], and bioavailability (e.g., labile-bound metal complex/strongly bound metal complex). It is therefore a challenge to identify and quantify the major species of elements such as Cr, Fe, Mn, As, and Hg in aquatic systems. Table 7.1 gives an overview of the levels of common trace metals in various aquatic systems. In general, speciation of trace metal species involves the following steps: 1. 2. 3. 4. 5.

Sampling Sample pretreatment/preservation/storage Extraction/derivatization/preconcentration of some (all) species Species separation Species detection

Each of these steps can modify the natural speciation distribution, and so the goal is to minimize their number. These steps will now be discussed for two groups of trace metals: Cr, Fe, Mn, and As (Section 7.2), and Hg (Section 7.3).

7.2 SPECIATION OF DISSOLVED Cr, Fe, Mn, AND As The major oxidation states of chromium in natural waters are III and VI. The ratio of their concentrations is highly variable depending on the specific physicochemical (e.g., redox, pH, etc.) conditions of the water column. Chromium(III) is the most stable oxidation state of this metal and an element essential for human health, whereas chromium(VI) is reported as being a possible human carcinogen and mutagen. Cr(VI) compounds are more soluble, mobile, and bioavailable than Cr(III) species.4,14 The presence of these two forms and their ratio depend on the pH,15 redox potential and reactions (oxygen concentration, presence of appropriate reducers, and photochemical redox transformation), and mediators acting as ligands or catalysts.16–18 It has been reported that Cr(VI) compounds are about 100 times more toxic than Cr(III) compounds owing to their high oxidation potential and ready passage through biological membranes.19 Fe and Mn appear to be increasingly important for photosynthetic carbon fixation by marine phytoplankton20,21 and thus also in the process of the earth’s warming up. In fact, the contemporary ocean is the largest sink of carbon dioxide, scavenging 45 gigatons of carbon per annum from the atmosphere, of which 11 gigatons are exported22 to the ocean interior. To sustain this C flux through marine ecosystems, essential elements such as Fe and Mn must be supplied in a ratio reflecting the composition of marine phytoplankton species. In most surface waters of the oceans, the concentrations

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of the essential trace elements are extremely low, especially during bloom periods. Moreover, they are present in different forms: in the dissolved phase they can be labile, strongly bound to organic ligands, or colloidal, this last form also being regarded as a fraction of the dissolved phase. Not all forms are suited for uptake by phytoplankton: in fact, only the free ions and the labile-bound complexes are. Nowadays, not only Fe but other trace metals as well, for example, Mn, Co, or Cu, are thought to limit primary production. It is thus a real challenge for oceanographers not just to assess correctly the very low levels of Fe and Mn in the oceans but also to carry out the speciation of these elements (total dissolved concentrations are at the nM level, labile forms 0.67 μM) in West Bengal and Bangladesh, where groundwater is the main source of drinking water.24 Extensive toxicity studies of As have shown that different forms exhibit different toxicities, as is the case with many environmental pollutants.25 Inorganic As species are more toxic than methylated compounds, arsenobetaine (AB), arsenocholine (AsC+), or arsenosugars. With the exception of the tetramethylarsonium ion, acute toxicity generally decreases with an increasing degree of methylation. Indeed, some organoarsenicals, such as AB, which is commonly found in seafood, and AsC+ are considered to be nontoxic toward living organisms, while the inorganic As species arsenite [As(III)] and arsenate [As(V)] have been identified as being the most toxic.25–27 Only four As species [As(III), As(V), MMA or monomethylarsonic acid, and DMA or dimethylarsinic acid] are mainly present and studied in the water column, because the arsenosugars, AB and AsC+ (the larger organoarsenicals) produced in and by aquatic organisms are not observed in the aquatic phase. The distribution of the most common arsenic species in natural waters depends mainly on the redox potential and the pH conditions.28 Under oxidizing conditions (i.e., surface waters) the predominant species is As(V), whereas under mildly reducing conditions (e.g., anoxic groundwaters) As(III) is the thermodynamically stable form.28 According to the literature, the MMA and the DMA fraction found in estuaries is highly variable depending on salinity, turbidity, temperature, and phytoplankton activity. For example, in the Humber and the Thames Estuary in winter, no methylated species were found; in midsummer, however, their levels ranged from 0% to 12% in the Humber, depending on the above-mentioned variables,29 with DMA concentrations from 0.27 to 2.7 nM, and made up about 8% of the dissolved arsenic concentration in the Thames.30 In winter, we were unable to find any methylated As species in the Zenne River (Belgium).27

7.2.1

IN SITU SPECIATION IN THE AQUATIC SYSTEM

Speciation is best carried out directly in the aquatic system, without sampling. This has been possible since the development of Diffusive Equilibrium in Thin Films (DET) and Diffusive Gradient in Thin Films (DGT) probes.31 The DET probe consists of a very thin gel layer that is immersed in the aquatic system and allowed to equilibrate with the bulk solution. The concentration of solutes in the gel is similar to that in the bulk solution for all solutes that can diffuse through the pore openings of the gel (some gels have open pores >5 nm and some gels have restricted pores <1 nm). The DGT

1.8 nM (unpublished data)a

DGT-ICPMS

a

19 nM34,a

4.0 μM (Fe-T)34

0.20 M (Fe(III))37 0.021 nM (Fe-T)38 0.010–0.11 nM39,40

These values are blank values. LODs for DGT depend in fact on the exposure time.

DET-ICPMS

0.10 nM (Cr(III) and Cr(VI))33 0.080 nM (Cr(VI))14 70 nM (Cr-T)34

8.0 pM (Cr(VI))32

0.10 M (Fe(II))37

Selective reagent (chemiluminescence)

0.60 pM (Cr(III))32

Electrochemistry (CSV)

Capillary reaction (chemiluminescence)

1.8 μM (Fe(III))36

0.020 nM35

LOD

2.7 μM (Fe(II))36

Sequential injection analysis (UV-VIS)

Resin-based column chromatography (GFAAS)

Speciation Procedure for Fe

0.096 nM (Cr(VI))14

0.096–0.13 (Cr(III))14 0.23–0.31 (Cr(VI))14 0.0077–0.012 nM (Cr(III) and Cr(VI))14 0.12 nM (Cr(III))14

Ion exchange (ICPMS)

Selective coprecipitation (FAAS) Bidirectional eletrostacking (AAS)

0.035–0.19 nM (Cr(III))14

LOD

Solid extraction (GFAAS)

Speciation Procedure for Cr

TABLE 7.2 LODs for Trace Metal Species in Aquatic Samples

Chelation (UV)

Sequential injection analysis (UV-VIS)

Speciation Procedure for Mn

17 nM (Mn-T)34 1.4 nM34,a

4.0 nM (Mn(II))9

89 nM (Mn(II))41 143 nM (Mn-T)41 0.39 nM42

LOD

HPLC-ICPMS

0.14 nM (unpublished data)a

2.0 nM (As-T)34

0.060–40 nM (As(III))43

0.30–0.80 nM (As(III))43

50 nM (As(III))43 0.3–53 nM (As(III))43 0.030 nM (As(V))43

0.10 nM (As(V))43

Solid extraction (ICPMS) IC-HG-GFAAS HG-AFS HG-GF-ICPMS

LOD 0.50–1.5 nM (As(III))43

Solid extraction (GFAAS)

Speciation Procedure for As

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technique is not a static (equilibrium) sampling method. Based on the mass transport control of solutes from the bulk solution to a backup resin, it makes use of two hydrogel layers: a polyacrylamide gel is the diffusive layer, which is backed up by a second thin film gel layer containing a resin, generally a chelex cation exchanger. With the DGT probe, it is thus possible to preconcentrate the solutes by increasing the exposure time in the solution. The limits of detection (LODs) obtained with the DET and DGT techniques are shown in Table 7.2. With a DGT device, Cr(III) can be bound to the chelex resin because of its cationic nature, whereas Cr(VI) is not bound to the resin (it has an anionic nature) but is present in the diffusive gel layer (as in a DET probe), reaching equilibrium with Cr(VI) in the aquatic system. Hence, Cr(VI) can be measured in the diffusive layer and Cr(III) in the resin layer.44 For Mn the same procedure can be adopted. The oxidized Mn(IV) species form colloids or even larger particles and will not be sampled by the DGT probe, whereas Mn(II) species are free or labile complexes. For Fe speciation, DGTs with open pores and with restricted pores are often used. Since in aquatic systems, Fe(III) is present mostly as a ligand complex or in colloidal form, the restrictive pore size excludes these forms and makes only Fe(II) species available to the restrictive DGT,45 whereas the open-pore DGT allows the passage of Fe(II) and small and labile Fe(III) complexes. In the case of arsenic speciation, As(III) and As(V) diffuse through the diffusive gel layer of the DGT, but only As(III) is immobilized on the chelating resin layer; As(V) remains in the diffusive layer as an anionic compound. The species separation obtained in this way is stable and no longer changes. In the laboratory, the solutes scavenged by the DGT resin or present in the diffusive gel layer can be solubilized and measured with a sensitive technique such as graphite furnace atomic absorption spectrometry (GF-AAS) or inductively coupled plasma mass spectrometry (ICP-MS), attaining detection limits of around 0.5 ppt. Laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS), which used to be applied to generate trace metal flux distributions in shells or sediments, is now utilized directly on the dry resin gels from DGT; with this technique a greater precision is achieved than with the classical ICP-MS.46

7.2.2

SAMPLING

For analyses not using the in situ DET and DGT techniques, classic sampling procedures are needed. Sample collection and storage are key aspects of the overall analysis methodology; hence, there is a need to standardize protocols for trace metal sampling in aquatic systems. Low-density polyethylene (LDPE), high-density polyethylene (HDPE), fluorinated HDPE, and Teflon [polytetrafluoroethylene (PTFE) or fluorinated ethylene propylene (FEP)] are traditional sampling materials (see e.g., Achterberg et al.8). A strict cleaning protocol needs to be followed. According to Achterberg et al.,8 the containers should first be immersed in 5% detergent for a week, then copiously rinsed with Milli-Q water, then immersed again in 6 M analytical grade HCl or HNO3 for two weeks, and stored double bagged until use. Immediately before sampling they should be rinsed three times with Milli-Q, and then rinsed three times with the sample before being filled finally.8 Our samples of surface water (North Sea, Scheldt River, and Zenne River) were collected manually from a rubber dinghy by submerging the precleaned sampling bottles approximately 20 cm beneath the water surface. Arm-length gloves were worn during sampling. The dinghy moved gently against the current during sampling and was positioned approximately 100 m upcurrent of the research vessel. When sampling from a rubber dinghy is not possible because of adverse weather conditions or when subsurface samples (10 m depth or more) are required, NOEX (Technicap, France) (Go-Flo type) sampling bottles and plastic-coated messengers, which are also thoroughly precleaned, are used.47 In addition, a Kevlar cable is mounted on the oceanographic winch. Filtration in the field is performed as soon as possible in a clean lab container or on a clean air bench close to the sampling spot. The filtration apparatus consists of an FEP separating funnel onto which a Teflon filter holder is connected. Filtration is performed under pressure using N2 gas.

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SAMPLE PRESERVATION AND STORAGE

Although sample preservation is to be avoided, sometimes there are no other options. For chromium sampling, the water sample was acidified at pH 2 and no Cr(III) was lost to the wall of the precleaned polyethylene (PE) or the polypropylene (PP) bottle for more than one month.48,49 While it is clear that Cr(III) is stable for a long time in an acidified sample, it was reported that acidification of coastal seawater resulted in the rapid reduction of Cr(VI) to Cr(III).48 On the other hand, a stable Cr(VI) concentration could be ensured at a nearly neutral pH, especially under a CO2 blanket.48,50 Traditionally, in order to prevent oxidation of unstable Fe(II) species, the water sample has to be filtered immediately after sampling (filtration of the sample in the field needs to be carried out under completely oxygen-free conditions) and stabilized: stabilization depends on the subsequent analytical method.51 Even when all sample treatment protocols are rigorously applied, Fe(II) is so easily oxidized that the initial speciation can be distorted simply by contact of the sample with air. Mn(II) oxidizes much more slowly than Fe(II): this reaction is about 107 times slower than that of Fe(II) at pH 8 and 25°C,52 reducing the risk of error during the speciation procedure. After filtration, only Mn(II) and Mn(IV) colloids remain in the sample. Filtered samples, mostly acidified, are commonly stored in precleaned Teflon bottles at 4°C. For As, contamination will occur only rarely as long as standard procedures for trace elements are followed. The preservation of samples is more likely to be one of the troublesome steps in As speciation analyses. Events like changes in oxidation state, changes induced by microbial activity, or losses by volatilization or adsorption have to be avoided.25 It has been observed that aqueous samples intended for total As determination did not sustain any losses during storage when kept in acid-washed glass, PTFE, or PE containers.53 As far as storage for As-speciation experiments is concerned, little information is available on appropriate storage conditions for As. An overview of the influence of critical factors for species stability (pH, temperature, light, and container material) and of procedures for the preservation of the integrity of species is given by Ariza et al.54 The recommended procedures are freezing, cooling, acidification, sterilization, deaeration, addition of ascorbic acid, and/or storage in the dark, but there is no general agreement on these procedures and some reports are conflicting. For samples in which bacteria may exist naturally, storage at low temperatures or even freeze-drying55,56 is required to prevent biological activity from modifying the nature of the sample. For aqueous samples, time and temperature studies report that, at higher concentrations (0.27 μM), immediate storage of filtered [0.45 μm polycarbonate filters (nucleopore)] and acidified [to 1% with HCl (supra-pure)] natural waters at about 5°C can preserve As(III) and As(V) concentrations for about 30 days.57 It is advisable that samples with lower As concentrations be kept in the dark at 4°C.58

7.2.4

ELECTROCHEMICAL SPECIATION

Cathodic stripping voltammetry (CSV) and adsorptive cathodic stripping voltammetry (AdCSV) allowed Cr speciation by direct determination of Cr(VI) in the presence of predominant Cr(III) levels with a detection limit (for LODs, see Table 7.2) of 0.08 nM for Cr(VI).59 Gledhill et al.60 used CSV to assess dissolved and total Fe concentrations in the North Sea, whereas Boye et al.61 used CSV to obtain Fe speciation in the northeast Atlantic Ocean. A much greater sensitivity for Fe speciation and lower LODs (for LODs, see Table 7.2) was obtained by CSV using an adsorptive and competing ligand.39 CSV was also used by a research group from Liverpool to determine dissolved and particulate Mn in the water column.62,63 Carbon film electrodes were used by Filipe and Brett9 to determine trace levels of Mn(II) in pore water samples; the detection limit was very low (Table 7.2). Electrochemical methods for arsenic determination were initially based on polarography with a dropping mercury electrode. More recent methods, based on anodic stripping voltammetry (ASV), anodic stripping chronopotentiometry (SC), and CSV, rely almost exclusively on the detection of As(III), since As(V) is detected with difficulty because of its perceived electro-inactivity.

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These methods use either a gold- or a mercury-based electrode.64,65 Despite past problems with determining inorganic arsenic species, Salaün et al.65 showed that As(III) can be determined by ASV using a gold microwire electrode at any pH, including the neutral pH typical of natural waters, whereas As(V) requires acidification to pH 1. Detection limits with this microelectrode are 0.2 nM As(III) at pH 8 and 0.3 nM combined arsenic (III + V) at pH 1 with a 30-s deposition time (Table 7.2). Additionally, copper is codetermined with this technique.

7.2.5

HYPHENATED METHODS

7.2.5.1 Exchange Columns (Trap and Elute) Cox and Mcleod66 passed their water samples through activated alumina microcolumns in the field, isolating and retaining both Cr(III) and Cr(VI) species. The microcolumns were then returned to the laboratory and inserted into a flow injection inductively coupled plasma-emission spectrometry (FI-ICP-ES) system for elution and quantification (the lowest results reported are around 40 nM). The pretreatment of the microcolumns and the FI-ICP-ES method was, however, complicated and time-consuming. Recently, Dogutan et al.67 and Latif et al.68 preconcentrated the Cr species on an exchange column and first eluted one species, and subsequently both of them. Special resin-based columns can perform iron speciation from water samples.51,69 Resin-based column chromatography procedures are attractive for several reasons. Mini- and microcolumns packed with ion exchange and adsorbing resins are effective for separating and preconcentrating simple cationic species of Fe(II) and Fe(III) or their complexes with different chromogenic reagents. Flow injection systems with resin-based columns make the procedures fast and simple to operate and allow automation. Automation of sample handling and analysis will especially minimize the risk of contamination and enhance the repeatability. A promising solid-phase extraction adsorbent for metals and more particularly As is nanometer TiO2 material and immobilized nanometer TiO2.70,71 Both As(III) and As(V), or As(III) alone, were quantitatively absorbed on immobilized nanometer TiO2 depending on the pH (for LODs, see Table 7.2). 7.2.5.2 Chromatography The most widely used separation techniques include high-performance liquid chromatography (HPLC), ion chromatography (IC), and capillary electrophoresis (CE), and all can be used in combination with other treatments such as hydride generation (HG), coprecipitation, and voltammetry (see e.g., Liang and Liu,71 Ronkart et al.,72 Sounderajan et al.,73 and Hu et al.74). For As, the most common of these methods is liquid chromatography combined with HG: this makes use of the ability of As species to form volatile hydrides when reacting with NaBH4. A novel separation method is capillary microextraction (CME) with an ordered meso-porous Al2O3 coating. This method can be used to simultaneously separate inorganic As(III)/As(V) and Cr(III)/Cr(VI).74 In many cases we are only interested in inorganic As speciation: this involves the determination of the total As content and the content of one of the two species, the other one being obtained by subtraction. The most popular analytical technique for the speciation of the predominant As species in an aquatic system [As(III), As(V), MMA, and DMA] is HPLC-HG-AFS; the technique used in our laboratory was described by Baeyens et al.27 The optimization of HPLC and HG-AFS coupling provided chromatograms of the four “anionic” arsenicals, similar to those in Figure 7.1, for a mixed standard of 6.7 nM of each of the compounds. The chromatographic conditions are as follows: column [Hamilton PRP-X100 (250 × 4.1 mm; 10 μm)]; mobile phase [KH 2PO4/K 2HPO4 buffer; 20 mM, pH 6.0 (HCl)]; flow rate (1 mL min-1); and injection volume (200 μL). For the HG system, the Ar gas flow rates are the same as for the total As determinations but they are modified for HCl (1.5 M; 1 mL min-1) and NaBH4 [2.5% (m/v); 1 mL min-1]. The detection limits (Table 7.2) are As(III) (0.40 nM), DMA (0.57 nM), MMA (0.55 nM), and As(V) (0.89 nM). Precision and accuracy on the lowest sensitivity scale were calculated from 10

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Retention time (min) 0.0

2.0

4.0

6.0

8.0

10.0

FIGURE 7.1 Chromatogram of a 0.5 μg As L -1 mixed standard of As(III), As(V), MMA, and DMA, using HPLC-HG-AFS. Order of elution: As(III)—DMA—MMA—As(V).

consecutive measurements of an artificial standard containing 5.3 nM of each of the four compounds of interest. The relative standard deviation varied between 7% and 13% whereas the recovery rate was within 92–98%, except for As(V), which was 81%. Accuracy measurements could not be made from measurements of reference material, since no liquid reference material, which is certified for the separate As compounds, was available. 7.2.5.3 Chemiluminescence and Colorimetric Reactions According to the review by Marques et al.,75 the most frequent pretreatment used for chromium speciation is complex formation. Extraction processes are frequently used after complex formation to extract the complexes formed prior to UV-VIS detection. Recently, the simultaneous determination of Cr(III) and Cr(VI) using an in-capillary reaction, CE separation, and chemiluminescence detection was reported with LODs (Table 7.2) for Cr(III) and Cr(VI) of 0.6 and 8 pM, respectively.32 Spectrophotometric techniques combined with flow injection analysis (FIA) and on-line preconcentration can meet the required detection limits for natural Fe concentrations in aquatic systems (Table 7.2) by also using very specific and sensitive ligands, such as ferrozine [3-(2-bipyridyl)-5,6bis(4-phenylsulfonic acid)-1,2,4-triazine], that selectively bind Fe(II). Determining Fe(II) as well as the total Fe after on-line reduction of Fe(III) to Fe(II) with ascorbic acid allows a kind of speciation.37 A drawback is that the selective complexing agents can shift the iron redox speciation in the sample. For example, several researchers have reported a tendency for ferrozine to reduce Fe(III) to Fe(II) under certain conditions.76 Most ferrozine methods involve sample acidification, which may also promote reduction of Fe(III) in the sample. Fe(II) is a transient species in most seawater environments and is rapidly oxidized to Fe(III); therefore, unacidified samples are required in order to maintain redox integrity.8 An alternative is to couple FIA with a chemiluminescence reaction.77,78

7.2.6

OTHER METHODS

In the 1980s, an analytical technique was developed for the study of chromium speciation in natural waters based on the atomization of electrodeposited species on graphite tubes.79 Two independent automated platforms consisting of an ultraviolet (UV) on-line unit and a chelation/preconcentration/

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matrix elimination module were specifically developed to process trace element samples, including Mn, on-site to avoid sample storage prior to ICP-MS analysis. This method has been used to determine total, labile, and organically bound dissolved Mn concentration42 (for LODs, see Table 7.2).

7.3 SPECIATION OF DISSOLVED Hg Although all forms of Hg are poisonous, the ecological and human health effects of mercury are generally related to environmental transformations of inorganic mercury to the toxic and biomagnification-prone compound monomethylmercury (MMHg). Significant improvements in instrumentation have been made in recent years, allowing reliable measurements of all Hg species, but traditional problems related to contamination, nonquantitative recoveries, and to questions about the possibility of artifact formation and transformations of methylmercury during the sample preparation and separation steps require the rigorous execution of validated analytical protocols. The importance of Hg speciation studies has been highlighted in various review articles published in the last 10 years by several authors.80–84 The relevant speciation methods depend on the nature of the sample (e.g., freshwater, seawater, and anoxic water) and the concentration level. In general, ambient Hg levels in natural aquatic systems, especially open ocean waters, are very low (for ppt–ppq levels, see Table 7.1) and require appropriate precleaning, sampling, and storage procedures. In terms of speciation of organomercury species, extraction is a very subtle step because (1) the whole species content may not be released and (2) artifacts can occur, so that some organomercury species may be destroyed or formed (interspecies exchange). Often, the extraction step for mercury speciation is applied in combination with a cleanup/preconcentration step such as distillation, solvent extraction, or headspace. Artifacts during the extraction-cleanup phase have been specifically studied with the latter methods. By using isotope-labeled compounds it is possible to study interspecies exchange. Precleaning of material, sampling, and filtration in the field are not very different from the procedures used for the other trace metals described above, except that for Hg borosilicate glass bottles can also be used, and that samples collected for volatile, metallic mercury Hg(0) and dimethylmercury (DMHg) species are not filtered. When filtration cannot be carried out in the field, samples should be kept unpreserved, cold, and in the dark. More specific information about our techniques can be found in Baeyens80 and Leermakers et al.47,84

7.3.1

SAMPLE HANDLING AND STORAGE

The most volatile forms present in water are Hg(0) and DMHg. They should be removed from the samples immediately after collection by purging and trapping on gold (for total gaseous Hg) and Carbotrap or Tenax (for DMHg). When purging and trapping in the field is not possible, samples should be collected in completely full glass bottles with Teflon-lined caps, as these species are lost rapidly (t1/2 = 10–20 h) from Teflon and PE bottles.85 Because acids can accelerate the oxidation of volatile species, these samples should be stored, refrigerated and unacidified, and processed within 1–2 days. After filtration, samples for reactive Hg (Hg-R) and total dissolved Hg (Hg-T) were acidified with 0.5% HCl.47 BrCl is also often used to preserve samples intended for Hg-T determination. The acidification of samples to be used for Hg-R determination was not recommended by Parker and Bloom,85 especially those with high levels of dissolved organic carbon (DOC). DOC may coagulate after acidification of the solution, with concomitant adsorption and precipitation of Hg-R. Labile Hg (Hg-R) appears to be relatively stable (days to weeks) in filtered, unpreserved samples. Samples designated for the determination of MMHg were stored deep-frozen and unpreserved.47 Alternatively, Parker and Bloom85 suggested storing freshwater and seawater samples for MMHg in the refrigerator and in the dark after the addition of 0.4% HCl or 0.2% H2SO4. Sulfuric acid was

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recommended for seawater to minimize Cl- levels, which interfere when the distillation extraction method is used.

7.3.2

ANALYTICAL METHODS FOR Hg(0), DMHg, Hg-R, AND Hg-T

Hg-T, Hg-R, DMHg, and Hg(0) were determined by cold vapor atomic fluorescence spectrometry (CVAFS) using an Au-amalgamation preconcentration step.86 Hg(0) was purged from the sample on a gold column in the field; DMHg on a Carbotrap column. Both were transferred to an analytical Au column in the laboratory and determined with CVAFS. Hg-R was measured using SnCl2 as a reducing agent; Hg-T was analyzed by BrCl oxidation and reduction with NH2OH.HCl prior to reduction with SnCl2.47,87 The detection limits were 0.025 pM for Hg(0) and DMHg, 0.075 pM for Hg-R, and 0.25 pM for Hg-T (see Table 7.2). The detection limit for Hg-T in a water sample without any pretreatment is much higher (10 pM) with ICP-MS, but ICP-MS is often used in combination with a cold vapor module or an Au column.

7.3.3

ANALYTICAL METHODS FOR MMHg

7.3.3.1 Extraction Procedures Total dissolved MMHg can be analyzed by aqueous-phase ethylation after separating MMHg from the interfering chloride matrix by extraction with methylene chloride.88 For a 200-mL sample a detection limit of 0.075 pM is achieved. An alternative method for the simultaneous extraction of Hg(II) and MMHg in natural waters at fM levels is to extract both into toluene as dithiozonates after acidification of the water sample, followed by back extraction into an aqueous solution of Na 2S and removal of H2S by purging with N2.89 Nagase et al.90 and Horvat et al.91 proposed vapor distillation in a stream of air or nitrogen at 150°C for the nonchromatographic separation of inorganic Hg and MMHg. In combination with the ethylation technique, Carbotrap or Tenax preconcentration, GC separation, and AFS detection,88,92 this quickly became the method of choice for the extraction of MMHg because of its high efficiency (practically 100% recoveries of MMHg), the elimination of inorganic Hg in the extract, and the formation of clean aqueous extracts that eliminate interferences in the ethylation step. However, investigations in the mid-1990s showed that the distillation procedure used to separate methylmercury from both water and sediment samples artificially generates MMHg in the presence of natural organic substances. A special issue of Chemosphere was published in 1999,93 summarizing the state-of-the-art regarding the artifact formation of MMHg during derivatization and analysis (during separation owing to the presence of the silanizing agent), and also during sample storage. 7.3.3.2 Gas Chromatographic Separation Methods Apart from the above-mentioned problems associated with the extraction of organomercurials, difficulties were also encountered with the chromatography of organomercury halides. The different packed and capillary columns used were reviewed by Baeyens.80 In order to prevent ion exchange and adsorption processes on the column (which cause undesirable effects such as tailing, changing of the retention time, and a decrease in peak areas/heights), passivation of the packing material with Hg(II) chloride in benzene (or toluene) is needed. Moreover, the more common GC detectors may lack the selectivity required for use in the speciation of Hg in environmental samples. For instance, electron capture detection (ECD) was commonly used for methylmercury speciation in environmental samples, but its unselective response required laborious cleanup processes of the extract in the organic phase. 7.3.3.3 Derivatization and Validation To overcome these problems, alternative methods involving precolumn derivatization of Hg species have been developed. These nonpolar derivatives can then be separated on nonpolar packed88,94 or

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capillary columns.95 Iodation with acetic acid,94,96 hydration with NaBH4,97,98 aqueous-phase ethylation with sodium tetraethylborate (NaBEt4),88 and derivatization with a Grignard reagent (ethylation, butylation, propylation, etc.)95 are the most commonly used methods. Aqueous-phase ethylation, room-temperature precollection, and separation by GC with CV-AFS detection have become the most frequently used techniques in laboratories involved in studies of the biogeochemical cycle of mercury. Like elemental Hg and DMHg, the ethylated species are volatile and can therefore be purged from solution at room temperature and collected on sorbents such as Carbotrap or Tenax. After thermal release, all the mercury compounds (natural or derivatized) are separated by cryogenic,88 isothermal,99 or temperature-programmed GC.100 Instead of being collected on Carbotrap or Tenax, the ethylated compounds may be injected directly into the GC column by headspace injection100,101 or cryotrapped on a fused silica column and desorbed by flash heating.102,103 As the Hg species are eluted from the column, they are thermally decomposed in a pyrolytic column (900°C) before being measured by an Hg-specific detector (e.g., CV-AFS, CV-AAS, QF-AAS, MIP-AES, and ICP-MS). It should be mentioned that the ethylation procedure cannot be used for the determination of other organomercurials; moreover, it is not clear whether ethylmercury compounds were originally present in the sample. Therefore, the usefulness of other derivatization agents has been investigated. Sodium tetrapropylborate (NaBPr4) was proposed by De Smaele et al.,104 and sodium tetraphenylborate (NaBPh4) by Abuin et al.105 and Grinberg et al.106 Sodium borohydride may also be used to form volatile methylmercury hydride, which is then quantified by gas chromatography in line with a Fourier transform infrared spectrophotometer.107 If derivatization of the native species is carried out, derivatization yields should also be assessed. In aqueous samples these yields are relatively easy to assess when a derivatized standard similar to the derivatized organomercury compound is available. Use of the standard addition method allows the derivatization yield to be determined. 7.3.3.4 GC Improvements Several techniques have been used to overcome the problem of low column loadings on capillary columns. Capillary columns have also been used after preconcentration of alkyl derivatives on a wide-bore fused silica column103 or by solid-phase microextraction (SPME).106 Multicapillary GC (MCGC) [919 capillaries, 1 m*40 μm id coated with 0.2 μm SE 30 stationary phase (Alltech)] coupled to ICP-MS103 allows column loadings and carrier gas flow rates to approach those of packed columns. The basic and unique features are the high speed of separation at large sample injection volumes with an exceptionally high range of volumetric velocities of the carrier gas at which the column retains its high efficiency. This makes plasma source detection ideally suited for MCGC, leading to a coupled technique with a tremendous potential for separation analysis. Solid-phase microextraction capillary gas chromatography (SPME-GC) is also an interesting preconcentration method. After derivatization with tetraethylborate, tetrapropylborate, or tetraphenylborate, the ethylated compounds are extracted by SPME on a silica fiber coated with polydimethylsiloxane (PDMS). SPME can be performed either in the aqueous phase or in the headspace. After SPME extraction, species are thermally desorbed, separated by GC, and analyzed.106 7.3.3.5 Liquid Chromatographic Separation Methods Applications of HPLC for Hg speciation studies have been reviewed by Harrington.83 Practically all HPLC methods for Hg speciation reported in the literature are based on reversed-phase separations, involving the use of a silica-bonded phase column and a mobile phase containing an organic modifier, a chelating or an ion pair reagent, and in some cases, a pH buffer. The interface to couple HPLC columns with the atomizer can be very simple, with a direct connection from the exit of the column to the nebulizer of the AAS or plasma detector. Unfortunately, the efficiency of the nebulizer is very low (1–3%), which limits the sensitivity. A general way to circumvent this lack of sensitivity is postcolumn derivatization to form cold Hg vapor. However, the generation of a cold vapor from organomercury species requires an extra step: their conversion to

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Hg(II). This conversion is usually on-line, but in an effort to analyze low levels of mercury species, some workers have developed on- and off-line sample preconcentration methods.108–110 Besides reversed-phase HPLC, IC has also been used to separate Hg species.111,112 IC enables the direct separation of more polar and ionic species, so that sample pretreatment can be simplified. The coupling of IC with CV-ICP-MS allows very low detection limits to be obtained.112 7.3.3.6 Detection Methods The development of a commercial, relatively inexpensive, extremely sensitive, and selective CV-AFS instrumentation in the late 1980s and 1990s113 made this the most popular detector in laboratories working on the biogeochemical cycling of Hg. In recent years, the use of ICP-MS in speciation analysis has increased tremendously. Besides its high sensitivity and selectivity, ICP-MS offers the opportunity to perform speciated isotope dilution mass spectrometry (SID-MS).114 Not only is this technique highly accurate and precise, the isotopically enriched isotopes can also be used as tracers to check for species transformations and extraction recoveries. However, to determine the low levels of Hg in natural aquatic systems that are quantifiable with a gold column and a CV-AFS instrument, ICP-MS is often coupled to either a cold vapor generation module or an Au column.

7.3.4

SPECIATION MODELING OF Hg

The extent of complexation of dissolved mercury in estuarine waters will vary markedly with the nature and concentration of the inorganic and organic ligands as well as their respective stability constants. The following equations describe the relations between the different species: 1. 2. 3. 4.

Hg(total) = Hg(labile) + Hg(nonlabile) Hg(labile) = HgLinorg + Hg(free)2+ + Hg(0) HgLinorg = SHg(free)2+ (Linorg(free)) Hg(nonlabile) = HgLorg + MeHg

The major species can be calculated using known values of equilibrium constants and the concentrations of the ligands Hg(total), Hg(labile), and MeHg: 5. bHgLn = [HgLn]/([Hg(free)2+][L]n), where bHgLn is the conditional stability constant of the complex HgLn, and [HgLn], [Hg2+], and [L] are the concentrations of the complex, the free mercuric ion, and the free ligand, respectively. A correct speciation involves a multitude of chemical equilibria, as any metal can form a complex with any ligand. Using the above equations, model simulations of the various Hg species in the Scheldt estuary were carried out using the TK-Solver program.115 A conditional stability constant of 1019 was estimated for Hg–humic acid interactions in the Scheldt.

ACKNOWLEDGMENT The authors gratefully acknowledge the financial support from the Interuniversity Attraction Poles Programme—Belgian State—Belgian Science Policy (TIMOTHY—P6/13). Anouk de Brauwere is a postdoctoral researcher of the Flanders Research Foundation (FWO).

REFERENCES 1. Cheng, K.P. and J.J. Jiao. 2008. Metal concentrations and mobility in marine sediment and groundwater in coastal reclamation areas: A case study in Shenzhen, China. Environ. Pollut. 151: 576–584. 2. Farnham, I.M., K.H. Johannesson, A.K. Singh, V.F. Hodge, and K.J. Stetzenbach. 2003. Factor analytical approaches for evaluating groundwater trace element chemistry data. Anal. Chim. Acta 490: 123–138.

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8

Immunochemical Analytical Methods for Monitoring the Aquatic Environment Javier Adrian, Fátima Fernández, Alejandro Muriano, Raquel Obregón, Javier Ramón, Nuria Tort, and M.-Pilar Marco

CONTENTS 8.1 8.2

Introduction ...................................................................................................................... Immunochemical Determination of Industrial Contaminants ......................................... 8.2.1 Polycyclic Aromatic Hydrocarbons ...................................................................... 8.2.2 Surfactants ............................................................................................................ 8.2.3 Organohalogenated Compounds ........................................................................... 8.2.4 Heavy Metals and Metalloids ............................................................................... 8.2.5 Other Industrial Pollutants: Bisphenol A .............................................................. 8.3 Immunochemical Methods for Pesticides ......................................................................... 8.3.1 Insecticides ........................................................................................................... 8.3.2 Herbicides and Plant Growth Regulators ............................................................... 8.4 Immunochemical Determinations of Pharmaceutical and Personal Care Products ..................................................................................................... 8.4.1 Antibiotics ............................................................................................................. 8.4.1.1 Sulfonamides ......................................................................................... 8.4.1.2 Fluoroquinolones ................................................................................... 8.4.1.3 Amphenicols .......................................................................................... 8.4.1.4 Tetracyclines .......................................................................................... 8.4.1.5 ß-Lactams .............................................................................................. 8.4.1.6 Macrolides .............................................................................................. 8.4.1.7 Other Drugs ........................................................................................... 8.4.2 Steroid Hormones ................................................................................................. 8.4.2.1 Estrogens ................................................................................................ 8.4.2.2 Androgens .............................................................................................. 8.4.2.3 Gestagens ............................................................................................... 8.4.2.4 Corticosteroids ....................................................................................... 8.5 General Summary ............................................................................................................. Acknowledgments ...................................................................................................................... References ..................................................................................................................................

140 142 142 145 147 149 150 151 152 154 158 158 160 161 162 163 164 165 165 166 166 168 169 169 169 170 170

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INTRODUCTION

In recent decades, efforts to better understand the occurrence, fate, and environmental effects of anthropogenic chemicals have focused largely on industrial compounds and agricultural pesticides. This emphasis has been in response to the increasing production of these chemicals, including the so-called emerging contaminants, such as pharmaceutical active ingredients and personal care products, their concentrated use, the potential risk of persistence, and their sometimes unknown acute and chronic toxic effects (see Table 8.1 for the most important groups of emerging pollutants).1 Pollutants can enter the environment in a great many ways.2 Some compounds, such as pesticides, are deliberately released during agricultural applications; others, like industrial by-products, get into our water and air resources during regulated and unregulated industrial discharges. On the other hand, pharmaceuticals and biogenic hormones are normally discharged into the environment through wastewater treatment plants (WWTPs), which are often not designed to remove them from the effluent. From there on, the transport, fate, and possible adverse consequences of these pollutants on human health and the ecosystem are frequently unknown or at best not clearly understood.3 Potential concerns include reproductive impairment,4–6 increased incidence of cancer,7 development of antibiotic-resistant bacteria,8 or the potentially elevated toxicity of chemical mixtures due to synergistic effects;9 these concerns demand extensive investigation of all possible situations. The aim of regulations and regulatory methods to assess and control the impact of these substances in the aquatic environment is to protect the ecosystem and public health while keeping watch on their contamination levels and potential negative effects. In addition to the REACH (Registration, Evaluation, Authorization, and Restriction of Chemicals) law (EC 1907/2006) regarding chemicals and their safe use, which came into force on June 1, 2007, there are specific regulations for protecting health and ensuring the good quality of all water resources, such as the Drinking Water Directive (DWD, the Council Directive 98/83/EC), the Bathing Water Directive (2006/7/EC), or the Urban Waste Water Directives (91/271/EEC and 98/15/EC). Moreover, the intention of the Water Framework

TABLE 8.1 Some of the Most Important Contaminants Needed to be Monitored Industrial Contamintants

Pesticides

Surfactants and metabolites Nonanionic Anionic Cationic

Insecticides Organochlorines Organophosphorus

Organohalogenated compounds Polychlorinated Chlorophenols Dioxins Polybrominated biphenyl ethers Bromophenols Heavy metals and metalloids As, Cd, Cr, Cu, Pb, Hg, Ag, Se, Zn, etc.

Herbicides/plant growth regulators Triazines Phenylurea compounds Chloroacetanilides Sulfonylureas

Industrial additives and others Phthalate esters Bisphenol A

Pharmaceuticals Antibiotics Sulfonamides Fluoroquinolones Amphenicols Tetracyclines ß-Lactams Macrolides Other drugs Diclofenac Indomethacin Nitrofurantion Paclitaxel Spectinomycin Steroid hormones Estrogens Androgens Gestagens Corticosteroids

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141

Directive (WFD, 2000/60/EC) is to provide an overall framework for a cleaner and safer aquatic ecosystem, particularly with regard to surface freshwater and groundwater bodies (i.e., lakes, streams, rivers, estuaries, coastal waters, etc.). Thus, in line with this directive, the Marine Strategy Directive (2008/56/EC) aims to achieve a good environmental status of the EU’s seawaters by 2021. Similarly, a River Basin Management Plan (RBMP) is being developed for implementation in each river basin district; each such plan must include knowledge of the particular pressures and impacts of human activities on the river basin in question, as well as protection programs, controls, and remediation measures. The first RBPM is scheduled to be published at the end of 2009; in parallel with it, the new Groundwater Directive (2006/118/EC) establishes a regime that sets underground water quality standards (QSs) and introduces measures to prevent or limit inputs of pollutants into groundwater. The aim of all these directives is to maintain water quality in all its aspects, including chemical pollution, on which this chapter will focus. Community policy regarding dangerous or hazardous substances in European waters was introduced almost three decades ago by Council Directive 76/464/EEC. This Directive is now integrated in the WFD (codified as 2006/11/EC). The main strategy against the pollution of surface waters involves the identification of substances and development of control measures. More than 100,000 existing chemicals have been identified in the European Inventory of Existing Commercial Chemical Substances (EINECS). Data collection on the potential adverse effects of these chemicals has led to 141 of them being classified as priority substances. The latest list of priority substances presenting a significant risk to or via the aquatic environment was published in Council Decision No 2455/2001/EC. The list identifies a further 33 substances or groups of substances that have been shown to be of major concern. Moreover, in July 2006, the EC adopted proposals for a new Directive to protect surface water from pollution by setting up Environmental Quality Standards (EQS, concentrations of pollutants which should not be exceeded) and measures to monitor pollution (COM(2006)397 final). Although for surface waters the WFD aims to ensure at least a minimum chemical quality, particularly in relation to very toxic substances, the case regarding groundwater is somewhat different: the assumption is that groundwater should not be polluted at all. Therefore, the WFD strategy includes a prohibition on direct discharges to groundwater and, to cover indirect discharges, requires groundwater bodies to be monitored so that any change in chemical composition can be detected. In order to achieve these objectives, more efficient analytical techniques need to be developed. This is so that the public health can be protected by ensuring that levels of pollutants remain below EQS concentrations and by providing, on a continuous basis, information on the fate of existing chemicals. A variety of multiresidue analytical procedures capable of analyzing an important number of chemicals10–14 in a single run have been reported in recent years. Most of them combine the high resolution of chromatographic methods [gas chromatography (GC), high performance liquid chromatography (HPLC), and ultra performance liquid chromatography (UPLC)] with the excellent detectability of sophisticated detectors like those based on mass spectrometry. In spite of this, these procedures lack the requisite sample throughput for a really effective assessment of the health of aquatic environments. The main limitations are due to the sequential nature of these analytical methods as well as the need to clean up and preconcentrate samples prior to analysis. In this context, immunochemical methods, which are based on the affinity of an antibody for an antigen (Figure 8.1), should be looked at as an interesting alternative for a number of reasons. Firstly, measurements are performed by default in aqueous media, which makes these methods excellent tools for the analysis of aqueous samples. Secondly, owing to high specificity and detectability of certain substances or groups of substances, it is often possible to analyze them directly in the same matrix without having to purify, extract, and preconcentrate the sample. It is also possible to develop a variety of immunochemical configurations targeted to particular analytical requirements. Thus, a great number of immunochemical methods for the on-site analysis of environmental pollutants have been reported or are commercially available.15–19 On the other hand, simultaneous analysis of many samples is possible by incorporating the immunoreagents on formats using 96- or 384-well microplates and developing formats with high sample-throughput capacities.20–22 Selective sample treatments based on immunosorbents yield very clean aqueous extracts; such techniques can

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Analytical Measurements in Aquatic Environments Antigen binding sites

F(ab)

2

L chain F(ab)

Fv

Fc

H chain lgG molecule

FIGURE 8.1 Basic H2L2 structure of the G immunoglobulins (IgG). It is formed by two pairs of polypeptide chains interlinked by disulfide bonds. The Fc fragment is the constant region and is involved in immune regulation, whereas the F(ab) (antibody binding fraction) fragment is the region that contains the variable fraction (Fv) with specific binding sites that allow interaction with Ag.

then be applied in tandem with some other type of immunochemical or chromatographic analysis.23–26 Recent years have witnessed interesting advances in the incorporation of selective immunoreagents into electronic devices, which emit optical or electrical signals in response to the presence of an analyte. Immunosensors have made it possible to develop integrated devices capable of handling data and of taking automated remedial action when the analyte is present.3,27–33 Since the reader will find extensive information in recent reviews on the fundamentals34–38 of these immunochemical analytical methods and examples of their application in environmental analysis,29,30,33,39–44 we will now concentrate our attention on the applicability of these methods to the determination of some of the most important pollutants in aquatic environments—specifically, marine and freshwater ecosystems and their biota. The chapter does not pretend to be an exhaustive review of what has been reported in the literature; rather, its aim is to provide the reader with representative examples of immunochemical analytical technologies that have either been applied to the aquatic environment or exhibit great potential in this respect. Examples of the several groups of chemicals have been selected according to their toxicological risk, relevance, and regular use or production.

8.2

IMMUNOCHEMICAL DETERMINATION OF INDUSTRIAL CONTAMINANTS

Worldwide industrial activity generates vast amounts of chemical residues such as metals, polycyclic aromatic hydrocarbons (PAHs), polyhalogenated biphenylethers, and surfactants. One of the main concerns regarding the contamination caused by such activity is the enormous amount of unknown substances generated as by-products during the manufacture of other chemicals. The highly toxic dioxins, for example, are released into the environment largely as the unwanted by-products of industrial processes. In addition, there is the risk of major accidents, like the Seveso accident in 1976, with dramatic consequences for the population. Immunochemical methods for following up and monitoring the emissions of some of these pollutants into the aquatic environment have been reported.

8.2.1

POLYCYCLIC AROMATIC HYDROCARBONS

PAHs are chemical compounds consisting of fused aromatic rings without any heteroatoms or substituents. They are formed mainly from the incomplete combustion of organic carbon-containing fuels such as wood, coal, diesel fuel, fat, or tobacco. PAHs can be found airborne in the gaseous phase or adsorbed to particles,45 in aqueous matrices like groundwater, wastewater, drinking water, or river water,46 and even adsorbed to solids in sediments or soils.47 The U.S. Environmental Protection Agency (EPA) includes 16 PAHs in the list of priority pollutants in wastewater to be

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TABLE 8.2 Immunochemical Techniques Developed for the Detection of PAHs Sensitivity Target Analyte Benzo(a)pyrenea

PAHs

Phenanthrenea

Technique ELISA

Water and sediments

ELISA

Tap, lake, and river water

ELISAc (SDI, Newark, USA) ELISAc (SDI, Alton, UK) ELISAc (Ohmicron, PA, USA) Immunosorbent-LC

Soil

Immunoaffinity and GC-MS Amperometric immunosensor Amperometric immunosensor

a b c

Matrix

Sediment

LOD 0.7 mg L-1 b 24 mg L

-1 b

5.5 mg kg-1

River water

IC50

Reference

20.5 mg L-1 b

50

65 mg L-1 b

51

3.2 mg L-1 b

54

255 mg kg-1

55

0.1–37 mg L-1 b

57

Surface water

0.002 mg L-1

48

Corals

25 mg kg-1

62

River water Tap water

5.0 mg L-1 6.3 mg L-1

18.0 mg L-1 26.0 mg L-1

58

Sea, river, and tap water

1.4 mg L-1 b

29.3 mg L-1 b

59

Indicator of total PAHs. LODs and IC50 calculated in buffer solution. Commercial kit.

monitored48 because of their carcinogenic, mutagenic, and toxic properties.7 The European Council Directive 98/83/EC concerning the quality of water intended for human consumption (WIHC) established a limit of 0.01 mg L -1 for benzo(a)pyrene, the lowest limit set for any individual chemical parameter in this directive. As can be seen in Table 8.2, several immunochemical techniques, principally enzyme-linked immunosorbent assays (ELISAs), have been developed and applied to environmental samples such as water, soil, and sediments with very good limits of detection (LOD).49–51 EPA has included commercially available ELISA kits in its list of official methods (Method 4035)52 capable of detecting PAH concentrations >1 mg kg-1 in soil samples.53–56 The usual ELISA configurations for the analysis of small molecules are shown in Figure 8.2. Most of the antibodies described were produced against one particular PAH congener, but because of their structural similarities they are in fact able to detect several PAHs. For this reason, different assays employ distinct target analytes as indicators of total PAH content, for example, phenanthrene,53,56 benzo(a)pyrene,50,51,54,55 or pyrene.49 When real samples are immunoassayed, PAH levels have often been overestimated due to cross-reactivity with other congeners in the same sample.50,54,57 In contrast, the underestimated PAH levels reported following the analysis of sediments55 or contaminated soil samples56 can be explained by the low extraction efficiency of the methods recommended in most commercial kits, where samples are merely shaken manually in the presence of an organic solvent. Nevertheless, the possibility must also be entertained that the sample contains PAHs with a low response factor to the particular antibody employed in the kit.49,53 Amperometric immunosensors employing electrodes directly printed with an immobilized competitor of the target analyte have also been investigated to detect phenanthrene in environmental samples. Following this approach, Fahnrich et al.58 achieved detection limits of 5 mg L -1 in river water and 6 mg L -1 in tap water samples. Moore et al.59 applied the same transducing principle to

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Analytical Measurements in Aquatic Environments (b) Indirect competitive ELISA

(a) Direct competitive ELISA Enzyme tracer

Analyte

Substrate

Antibody

Colorimetric response

Substrate

Analyte

Anti-IgG Labelled

Coating Antigen

Antibody Solid support

Solid support

Colorimetric response

Solid Support

Solid Support

FIGURE 8.2 Scheme of the ELISA formats most frequently used for the analysis of low-molecular-weight analytes. (a) Direct competitive ELISA: the Ab is coated on the surface and a competition is established between the analyte and the enzyme tracer. After the washing step, a substrate is added to produce a chromogen product that is easily quantified. (b) Indirect competitive ELISA: a coating antigen is immobilized on the solid support while the specific IgG and the analyte are in solution during the competition step. After the removal of unbound reagents, a secondary IgG labeled with the enzyme (IgG-enzyme), which specifically recognizes the Ab, is added. Finally, after another washing step, the amount bound is also quantified by the addition of the substrate solution.

analyze phenanthrene in sea, river, and tap water samples, obtaining an LOD of 1.4 mg L -1. These biosensors have great potential in field assays, where simple, quick detection systems are required: unlike the microplate ELISA methods, the measurements do not involve many operational steps. Biosensors based on surface plasmon resonance (SPR) have also been reported, although they have not often been used to analyze PAHs in real environmental samples. Figure 8.3 illustrates both the SPR principle and the schematic representations of a typical sensogram obtained with this technique. Gobi et al.60 used this methodology to analyze benzo(a)pyrene in buffer with promising results (LOD = 0.1 mg L-1). Liu et al.61 report the use of an immunosensor based on piezoelectric signal transduction for the analysis of benzo(a)pyrene, pyrene, and naphthalene compounds; when measuring buffered samples, this device can achieve an LOD in the nM range.

n2

n2

n1

n1

wash

Regeneration

wash

Regeneration

wash

Regeneration

wash

Regeneration

q′ shift in SPR angle wash

Regeneration

wash

Shift in SPR angle (q′–q)

q

0 ng/mL 0.1 ng/mL 1 ng/mL 10 ng/mL 100 ng/mL 1000 ng/mL

FIGURE 8.3 Sensogram generated by SPR principle for the constant concentration of antigen and antibody, and the varying concentration of analyte. Surface plasmons are excited by the light energy at a critical angle (q) causing an oscillation and the generation of an evanescent wave. Under this condition a decrease in the reflected light intensity is observed. The angle q depends on the dielectric medium close to the metal surface and is therefore strongly affected by molecules directly adsorbed on the metal surface. This principle allows the direct detection of the interaction between the analyte and the antibody.

Immunochemical Analytical Methods for Monitoring the Aquatic Environment

145

As an alternative, immunoaffinity procedures have been developed to selectively extract PAHs from environmental samples. Thomas and Li62 demonstrated the greater efficiency of immunoaffinity methods in comparison with conventional extraction procedures. Bouzige et al.48 prepared an immunosorbent for use in an on-line analytical procedure, followed by liquid chromatography coupled to fluorescence detection, to monitor surface water samples. The sensitivity of the fluorescence detection in combination with the selectivity of the immunosorbent (IS) extraction enabled PAH compounds to be detected at levels between 2 and 10 ng L -1.

8.2.2

SURFACTANTS

Surfactants are very common water pollutants, mainly because of their extensive use in detergent formulations that are directly discharged into the environment via wastewater.63 They are usually organic compounds described as being amphiphilic, that is, containing both hydrophobic and hydrophilic groups. The most commonly accepted and scientifically sound classification of a surfactant is based on the charge present in the hydrophilic portion of the molecule after its dissociation in aqueous solution. Anionic surfactants are based mainly on sulfate, sulfonate, or carboxylate compounds: examples include linear alkylbenzene sulfonates (LAS), fatty alcohol sulfates (FAS), alkyl sulfonates (AS), alkyl ether sulfates (AES), and sodium dodecyl sulfate (SDS).64 Commercial LAS, which represent more than 40% of all surfactants, consist of a mixture of at least 20 compounds, including isomers.65 Residues of LAS, as well as their metabolites, the sulfophenyl carboxylates (SPCs), have been found in marine sediments66 and in surface waters from the low mg L -1 up to the 500 mg L-1 range.67–69 On the one hand, the toxicity of these compounds is low, but on the other, they may assist the permeation of other pollutants into aquatic biota.70 Nonionic surfactants, such as alkylphenol ethoxylates (APEs) and alkyl ethoxylates (AEs), do not ionize in aqueous solution; they are extensively used in detergent formulations or as stabilizers in plastics. The main components of APEs are isomers of nonylphenol ethoxylate (NPE) and to a lesser extent, compounds related to octylphenol ethoxylate (OPE). Alkylphenols (APs), APE metabolites, and their halogenated derivatives are much more persistent in the aquatic environment and thus give reason for concern. Nonylphenol (NP) and octylphenol (OP) are listed as surface water priority substances; they are endocrine disruptors with powerful estrogenic effects.71,72 Accordingly, the OSPAR commission (from the Oslo and Paris conventions),73 whose brief it is to protect the marine environment of the North-East Atlantic, decided to phase out the use of APEs by the year 2000.74 Nevertheless, monitoring of APEs will still be necessary in the coming years. Finally, the class of cationic surfactants includes nitrogen compounds such as fatty amine and quaternary ammonium salts (QAS), in which the hydrophobic groups are attached to positively charged nitrogen. These surfactants, which also have a biocide effect, are in general more expensive than the anionic ones and therefore less often used.64 Their poor solubility and tendency to adsorb to solids or to form complexes with anionic substances reduce the risk to the aquatic environment. The application of immunoassays to the analysis of surfactants started in 1982 with the determination of Triton X, one of the best known APEs, with ELISA achieving detection limits in the mg L -1 range.75 Since then, numerous immunochemical techniques have been developed, mainly to detect anionic and nonionic surfactants in the environment (Table 8.3). With regard to anionic surfactants, Farré et al.76 and Ramón-Azcón et al.77 reported an immunoassay for LAS determination in wastewater samples (LOD = 2 mg L -1). The assay also identified, with a high level of cross-reactivity, the long SPC chain that is formed after LAS degradation. Analyses can be performed directly in wastewater merely by diluting the samples 10-fold to eliminate matrix interferences. Similarly, Estevez and co-workers recently reported an immunoassay for short alkyl chain SPCs, which are the final degradation products of LAS.78 Because these products are highly polar, it is quite difficult to analyze SPCs if an extraction/preconcentration step is necessary. In contrast, immunochemical methods allow the direct determination of these chemical markers in aqueous samples. Thus, Zhang et al.79 developed a sequential injection analysis (SIA) combined

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Analytical Measurements in Aquatic Environments

TABLE 8.3 Immunochemical Techniques Developed for the Detection of Surfactants Sensitivity Target Analyte AEs APEs

APs LASs

a

Technique

Matrix

LOD

IC50

Reference

12 mg L-1 a

89

71 mg L-1

89

ELISA (tube assay)

Tap and river water

2 mg L-1 a

ELISA (plate assay)

Tap and river water

20 mg L

-1

ELISA

River water

16 mg L-1 a

79 mg L-1 a

63

ELISA

Polluted and tap water

10 mg L-1 a

246 mg L-1 a

72

Sequential injection CL assay ELISA

River water

10 mg L-1

30 mg L-1 a

86

Surface river water

mg L-1 range

SPR

Marine products, shellfish

ELISA

Wastewater

IS fluorescence detection assay FPIA

Waste- and groundwater

7 mg L

Waste- and groundwater

30 mg L-1

87 90

-1

10 mg kg

-1 a

1.8 mg L -1

-1 a

28,1 mg L

76 81 394

LODs and IC50 calculated in buffer solution.

with a chemiluminescence detector and neodymium magnet to perform magneto-immunoassay experiments for the analysis of LAS; they achieved an LOD of 25 mg L -1. Moreover, SánchezMartínez et al.80 developed a very sensitive fluorescence polarization immunoassay (FPIA) for analyzing LAS in wastewater and groundwater samples. Previously, the same authors had developed an immunoaffinity chromatography procedure followed by fluorescence detection to analyze LAS in tap water, groundwater, and wastewater samples.81 Recoveries were between 86% and 111% with dodecylbenzenesulfonate (LDS) as analyte (LOD = 7 mg L -1). The immunochemical determination of APEs and AP has been undertaken by several research groups63,72,82,83 (for further details, see the review by Estevez-Alberola and Marco84), although the detectability achieved is not good enough to analyze NP at the EQS value established for all surface waters (0.33 mg L -1).85 An LOD of 10 mg L -1 has recently been reported for a chemiluminescent immunoassay of APE.86 Previously, a highly sensitive and reproducible ELISA method had been described for NP, but the LOD obtained (2.3 mg L -1) was again still insufficient.82 This is why it is often necessary to include a preconcentration step prior to immunochemical analysis. The precision and accuracy of most of these ELISAs have therefore been evaluated by measuring these surfactants in spiked river samples, following a solid-phase extraction (SPE) procedure; recoveries have been good: 85–118%.63,87 The validation studies carried out by several groups have also shown good correlation with chromatographic methods,72,76,88 although some samples analyzed were clearly overestimated. The accuracy of the APE immunoassay mentioned above86 was also successfully evaluated by measuring spiked river samples. Usually, a wide cross-reactivity pattern is observed, in which APEs with a distinct number of ethoxylate units are detected in addition to AP and certain carboxylate metabolites. A highly selective ELISA for AEs has also been developed and evaluated by measuring different spiked water matrices, such as distilled, tap, and river water samples, with recoveries reported to be in the 75–134% range.89 Furthermore, an SPR Biacore sensor was applied by Samsonova et al.90 to detect NPs in different shellfish matrices like mussels, oysters, cockles, and scallops. The detection limits obtained for all the aquatic biota samples were around 10 mg kg-1,90 which is good enough considering the QS estimated for aquatic biota [10 mg NP kg-1 food (wet weight)].91 Several amperometric biosensors have been described, but none which might be suitable for aquatic

Immunochemical Analytical Methods for Monitoring the Aquatic Environment

147

environment monitoring. Rose et al.,92 for example, analyzed APE and AP in buffer using a capillary immunoassay with subsequent amperometric detection, and Evtugyn et al.93 developed another amperometric immunosensor for the analysis of NP with an LOD of 10 mg L -1. Several ELISA methods for determining cationic surfactants have been reported although we have not found any examples of their application to real environmental samples. The detectability obtainable by these methods is very good: an LOD of 0.04 mg L -1 has been reported for benzyldomethyldodecylammonium chloride (BDD12AC), a component of benzalkonium chloride (BAK).94

8.2.3

ORGANOHALOGENATED COMPOUNDS

The toxicity, bioaccumulative potential, and ecological impact of organohalogenated substances such as polychlorinated biphenyls (PCBs), polychlorinated dibenzofurans (PCDFs), polychlorinated dibenzo-para-dioxins (PCDDs), or polybrominated diphenylethers (PBDEs) have been extensively reviewed.95–98 All are referred to as persistent organic pollutants (POPs), that is, chemical substances that remain in the environment, bioaccumulate through the food chain, and pose a risk to human health and the environment. The international community is calling for action to reduce and then eliminate the production or formation of these substances and to monitor their emission. In this case, the detectability obtainable by analytical methods should be very low, since the limits established for these residues are in the ng per liter range. PCBs, which have been commonly used as lubricants, immersion oils, or fire retardants, are normally formed by the chlorination of biphenyl in the presence of an FeCl3 catalyst. PCB production was banned in the 1970s because of the high toxicity of most PCB congeners and mixtures. The number and the location of chlorine atoms in a specific PCB congener determine its physicochemical properties, environmental pathways, and toxicity. Isomers with a higher chlorine content bind preferentially to organic matter present in the solid phase; consequently, they are not easily degraded and are also poorly leached from sediments by water.99 On the other hand, some PCBs are more mobile, hence their tendency to volatilize, and therefore to circulate, in gaseous form, through different environmental compartments.100 PCBs are classified as a probable human carcinogen by EPA, which has established a maximum contaminant level goal of zero and a maximum contaminant level and practical quantification limit of 0.5 mg L -1 in drinking water.101 In the USA, regulatory limits for soil remediation vary according to state and site, but in general are 5 or 10 mg g-1 for industrial restricted access areas and 1 or 2 mg g-1 for residential access areas.102 For this reason, EPA has established method 4020, a procedure for screening soils and nonaqueous waste liquids, to determine when total PCBs are present at concentrations above 5, 10, or 50 mg kg-1.103 Table 8.4 shows other results regarding the analysis of organohalogenated compounds in environmental matrices. A commercially available ELISA test (PCB RaPID Assay®) has also been used to analyze these compounds; an LOD of 0.6 mg g-1 was obtained in mussel tissues.104 Lawruk et al. applied the same kit but with super paramagnetic particles as the solid support to analyze soil and water samples; they obtained detection limits of 0.2 mg L -1 and 500 mg kg-1, respectively.105 Another commercial ELISA kit (EnBioTec Laboratories) was evaluated for PCB 118 determination in retail fish samples (LOD = 0.05 mg L -1).106 Now let us take a brief look at other approaches. Zhao et al.107 developed an optical immunosensor consisting of a quartz crystal fiber coated with partially purified polyclonal antibodies to detect PCBs in soil and water samples. The optical signal was generated by the fluorescence produced when the 2,4,5-trichlorophenoxybutyrate fluorescein conjugate binds to the previously coated antibody.107 Electrochemical immunosensing strategies using carbon-based screen-printed electrodes as transducers in a direct competitive immunoassay have also been applied in the analysis of PCBs in marine sediment extracts108,109 (LOD = <1 mg L -1). Pribyl et al.110 developed a piezoelectric quartz crystal (PQC) immunosensor for the in situ determination of different PCB congeners in soil toluene extracts without any additional purification step. Also, a high-performance immunochromatographic (HPIAC) procedure has been successfully used as a cleanup method to isolate PCBs from water samples.111

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Analytical Measurements in Aquatic Environments

TABLE 8.4 Immunochemical Techniques Developed for the Detection of Organohalogenated Compounds Sensitivity Target Analyte PCBs

Matrix (Pretreatment)

LOD

IC50

Reference

PQC immunosensor

Soil samples

6 mg L-1

110

118

ELISA (EnBioTec Labs)

Fish muscle tissue

0.05 mg L-1 a

106

Aroclor® 1248 Aroclor® 1242 Aroclor® 1016

Immunomagnetic amperometric immunosensor

Marine sediment extracts

0.4 mg L-1 0.5 mg L-1 0.8 mg L-1

108,109

ELISAa (PCB Assay®)

Mussel tissue

600 mg kg-1

104

MAG particle IA (PCB RaPID Assay® kit)

Water Soil

0.2 mg L-1 500 mg L-1

105

10 mg L-1

107

0.028 mg kg-1

121

Aroclor® 1254

Aroclor® 1242 PCDDs (TMDD) a

Technique

Fiber optic immunosensor

Soil, river, and bay water

ELISA

Soil

24 mg L-1 8 mg L-1 94 mg L-1

0.123 mg kg-1

Commercial kit.

Other immunochemical techniques, not applied to environmental samples as yet, could be interesting for the future analysis of these residues.112,113 Immunochemical methods have also been reported for PCDDs and PCDFs. These substances are unintentionally formed during combustion processes and in the synthesis of chlorine gas and other chemicals used in the bleaching procedures of the pulp or paper industry.114,115 PCDDs have 75 positional congeners with different grades of toxicity, 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) being the most toxic. The extremely low water solubility of these compounds,116 which is approximately 1000-fold lower than that of PCBs and PAHs, has significant downstream effects on the development of immunoassays because they are applied in aqueous media. EPA has established an official immunoassay method (4025) based on a commercially available ELISA kit that uses polyclonal antibodies for the analysis of these compounds in soil samples at 0.5 mg kg-1 levels.117 Harrison and Carlson developed both a tube test and a microplate assay using one of Stanker’s monoclonal antibodies118,119 and obtained detection limits of 167 and 50 pg L-1 for TCDDs in soil samples.120 The use of accelerated solvent extraction (ASE) followed by ELISA for the rapid screening of dioxin-contaminated soils has been reported recently.121 An immunoaffinity chromatography method for the purification of polychlorinated dibenzo-p-dioxins and furans from biological samples was explored with the aim of simplifying the cleanup procedure and thereby reducing the time and cost of analysis.122 A study of the effect of organic solvents on the development of an ELISA has also been reported; an IC50 of 0.24 mg L -1 for TCDD was obtained.123 Additionally, a piezoelectric immunosensor system was developed for the rapid detection of PCDDs primarily in buffer. In this case, the antibodies deposited in the quartz crystal resonator were able to quantitatively detect concentrations between 0.01 and 1.30 mg L -1.124 Finally, PBDEs—mainly three commercial mixtures known as Penta-BDE, Octa-BDE, and Deca-BDE—are still widely used as flame retardants in products such as polymers, resins, electronic devices, building materials, textiles, and the polyurethane foam padding used in furniture and carpets. The intensive production and use of these compounds has made them ubiquitous in the environment and in biota.125,126 EPA is working with industry, governments, and environmental and public health groups to research and better understand the potential health risks posed by these substances.127 The European Commission is also aware of these risks to the environment and public health and has established EQS in the low ppt level. Thus, for Penta-BDE, the annual average (AA) EQS is 0.0005 mg L -1 for inland surface waters and 0.0002 mg L -1 for other surface waters. There

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Immunochemical Analytical Methods for Monitoring the Aquatic Environment

have been a few attempts to develop immunochemical methods for polybrominated flame retardant compounds. An ELISA kit for the analysis of PBDE is commercially available from Abraxis LLC. Based on the use of magnetic particles, this kit is addressed to the BDE-47 and BDE-99 congeners that compose the Penta-BDE formulation; LOD for the 47th congener is <25 ng L -1. Shelver et al.128 have reported an ELISA with an IC50 value of 28 mg L -1 for BDE-47 in buffer.

8.2.4

HEAVY METALS AND METALLOIDS

Heavy metals are also considered dangerous and persistent environmental contaminants. At least 20 are known to be toxic in some way and fully half of these, including As, Cd, Cr, Cu, Pb, Hg, Ni, Ag, Se, or Zn, are released into the environment in sufficient quantities to constitute a risk to human health. Metals bind easily to soils or sediments, and in this form they are relatively nontoxic; but changes in the weather or medium pH in combination with other environmental factors can mobilize them, thereby increasing their availability and effective toxicity. For this reason, sites contaminated with heavy metals must be monitored regularly. By way of example, mercury exceeds the 1 mg kg-1 action level, established by the U.S. Food and Drug Administration (FDA), in many marine and freshwater fish samples. For mercuric chloride used in medicine, the minimum risk level for Hg exposure is 0.007 mg kg-1 per day.129 EPA has therefore certified an immunoassay (Method 4500) that provides a screening procedure for the determination of mercury in soils at concentrations up to 0.5 mg kg-1. On the other hand, the Lead and Copper Rule (LCR), introduced by the EPA in 1991, established an action level of 0.015 mg L-1 for lead and 1.3 mg L-1 for copper based on the 90 percentile level of tap water samples.130 Another method (4510), again proposed by EPA, also determines lead in water and soil by means of an immunoassay.131 Nowadays, many of the heavy metals mentioned above are also regulated by the European Union; in water for human consumption, the permitted levels of chromium and mercury are 50 and 1 mg L -1, respectively.132 Moreover, cadmium and its compounds are among the 33 priority substances with an EQS of 0.08 mg L -1 in water listed in the proposal for a Directive [COM(2006)398 final] presented by the European Commission. Basically, there are two ways of producing antibodies against heavy metals. Firstly, when the immunogen consists of a heavy metal bound to a chelator like ethylenediaminetetraacetic acid (EDTA), the antibodies raised do not recognize the metal itself but identify the entire structure.133–135 On the other hand, if the antibodies are produced directly against the heavy metal attached to a suitable immunogen,136,137 the free metal can be recognized instead of the cage-like chelate structure. Wylie et al.137 developed highly specific antibodies for mercury using a glutathione complex, which is the basis of the only commercially available metal ion immunoassay (BiMelyze® Mercury Immunoassay). Alternatively, Barbas et al.138 reported the isolation of recombinant antibody fragments that preferentially recognize certain metals complexed to iminodiacetic acid. Some examples of immunochemical techniques applied to detect heavy metals in environmental samples are given in Table 8.5.

TABLE 8.5 Immunochemical Techniques Developed for the Detection of Heavy Metals Sensitivity Target Analyte

Technique

Matrix

LOD

IC50

Reference

Cd(II)

ELISA

Environmnetal water samples

7 mg L-1

—

134

Hg(II)

ELISA

Water (EPA samples)

0.5 mg L-1

—

137

ELISAa (BiMelyze®)

Scallop tissue extract

100 mg kg-1

—

395

FPIA

Soil

20 ng kg-1

—

140

Pb(II) a

Commercial kit.

150

Analytical Measurements in Aquatic Environments (a) Formation of chelated forms of metal ions

+ Metal

Chelator Metal-chelator complex

Antibody Metal-chelator-HRP

(b) Immunoassay for heavy metals Chromogenic substrate Colorimetric response

FIGURE 8.4 Scheme of the ELISA format most commonly used for the analysis of heavy metals, where antibodies recognize chelated forms of metal ions.

ELISAs for detecting cadmium(II), nickel(II), lead(II), and mercury(II) in water samples have also been reported.134,139 The most common ELISA format used for the analysis of these compounds can be seen in Figure 8.4. Similarly, an FPIA used polyclonal antibodies raised against the lead(II)-EDTA chelate to detect the metal in soils, solid waste leachates, airborne dust, and drinking water samples.140 Moreover, the Kin ExA™ 3000 automated immunoassay instrument was adapted to analyze Cd(II), Co(II), Pb(II), and U(VI) metals in groundwater samples.141 On the other hand, monoclonal antibodies, raised against the Cd-EDTA complex, have been used to develop an immunochromatography (IC) procedure for the quick testing of Cd in food (LOD = 0.3 mg kg-1).135 The development and validation of a one-step immunoassay for the determination of Cd(II) in human serum with an LOD of 0.24 mg L -1 has also been described,133 as has the optimization and validation of an immunoassay that measures soluble indium at 0.005 mg L -1 in buffer.142 An alternative way of detecting the presence of heavy metals is to use molecular biomarkers such as the diagnostic and prognostic tools used in marine pollution monitoring. Metallothioneins (MTs) are synthesized by toxic metals such as Cd, Hg, and Cu by chelation through cysteine residues and act as biomarkers of metal exposure in both vertebrates and invertebrates. These biomarkers are used with a range of molecular approaches to evaluate the exposure of various sentinel marine organisms, for example, mussels, clams, oysters, snails, and fishes, to metal contaminants. The demonstration that MTs from a wide variety of fish species are recognized by an antiserum raised against one piscine MT has enabled the development of immunotechniques based on ELISA143 and radioimmunoassay (RIA) procedures144 for the quantification of these compounds. A competitive solid-phase assay based on dissociation-enhanced lanthanide fluoroimmuno-detection (DELFIA) of anti-MT monoclonal antibody bound to a solid phase has been reported.145 An electrochemical determination of MTs by square wave cathodic stripping voltammetry has also been developed and optimized.146

8.2.5

OTHER INDUSTRIAL POLLUTANTS: BISPHENOL A

Among the emerging pollutants of industrial origin, Bisphenol A [2,2 bis(4-hydroxydiphenyl)propane] (BPA) has special relevance since it was one of the first chemicals discovered to mimic estrogens as endocrine disrupters.147 This compound was first reported by Dianin in 1891.148 BPA is produced in large quantities worldwide, mainly for the preparation of polycarbonates, epoxy resins, and unsaturated polyester-styrene resins.149 The final products are used in many ways, such as coatings on cans, powder paints, additives in thermal paper, in dental composite fillings, and even as antioxidants in plasticizers or polymerization inhibitors in polyvinyl chloride (PVC). To a minor extent, BPA is also used as precursor for flame retardants such as tetrabromobisphenol A or tetrabromobisphenol-S-bis(2,3-dibromopropyl) ether.150 This substance can enter the environment

Immunochemical Analytical Methods for Monitoring the Aquatic Environment

151

TABLE 8.6 Immunochemical Techniques Developed for the Detection of Bisphenol A Sensitivity Target Analyte Bisphenol A

a

Technique TIRF immunosensor SPR immunosensor

Matrix Water MilliQ water Groundwater River water

LOD (μg L-1) a

0.005 0.014 0.168 0.292

IC50 (μg L-1)

Reference

— 0.86 5.12 8.38

163 162

LODs and IC50 calculated in buffer solution.

via the effluent from the factories producing it because it is not completely removed during wastewater treatment.151,152 Several studies have demonstrated that BPA released to ground or surface water may be strongly adsorbed to soil or sediments.153–155 Several ELISA applications have been developed to determine BPA in environmental and industrial waste samples:156,157 Zhao et al.158 obtained an LOD of 0.1 mg L -1 in real water samples. Recently, immunosensors have appeared on the market to complement conventional immunoassays for the analysis of this compound (Table 8.6). Optical SPR immunosensors have been reported to analyze BPA in buffer,159–161 while a fully automated sensor called River ANAlyzer (RIANA), based on a combination of fluorescent labels and the evanescent wave principle, achieved an LOD of 14 ng L -1 in natural water samples.162,163 Moreover, an impedimetric immunosensor, based on label-free direct detection of BPA with a quartz crystal microbalance, has been reported to obtain a detection limit of approximately 0.3 mg L -1 in human serum.164 Park et al. demonstrated the effectiveness of piezoelectric immunosensors as a valuable alternative screening method for BAP environmental monitoring, achieving an LOD of 0.1 mg L -1, although so far, only in buffer.165 Further immunoaffinity chromatographic methods have been developed with the aim of improving the analytical procedure of BPA in biological fluid samples166 and in canned food.167 The same approach could be used to shorten cleanup steps, as well as the cost and time of analysis of other environmental samples.

8.3 IMMUNOCHEMICAL METHODS FOR PESTICIDES Pesticides are chemical substances used for preventing or limiting the damage caused by pests. Thus, unlike other groups of chemicals, pesticides are intentionally released into the environment. Moreover, there is a high risk of these chemicals turning up in the food chain: foodstuffs may become contaminated during agricultural production, processing, packaging, and storage. Owing to the sheer volume of their usage, coupled with their universal distribution, environmental persistence, and toxicological properties, pesticides are considered a major public health hazard. Agricultural pesticides may lead to contamination of surface and groundwaters by drift, runoff, drainage, and leaching.168 Surface water contamination may have ecotoxicological effects on aquatic flora and fauna as well as on human health.169,170 In the aquatic ecosystem, there is a continuous interchange of these compounds between the land, sediment, sediment–water interface, interstitial waters, aquatic organisms, and air–water interface. The distribution of pesticides between water and biotic materials can affect their dynamics in the ecosystem. Thus, their mobility, possible transformation, and biomagnification constitute a real threat to human health, wildlife, and the entire environment. This situation is reflected by the number of analyses on the influence of pesticides on particular aquatic ecosystems,171–179 and also by the presence of these biocides on most governmental priority lists of compounds that should be monitored. Intensive research has been carried out during the last 20 years aiming to develop analytical immunochemical technologies with improved

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capabilities regarding detectability and sample-throughput capabilities for pesticide analysis in environmental matrices.41,180–185 In the following, we will take a brief look at some of the most important of these methodologies and their application to the aquatic environment; the reader will find more detailed information in recent reviews.25,41,43

8.3.1

INSECTICIDES

Used in agriculture to combat insect pests since the 1940s, insecticides include several chemical families that constitute a serious environmental risk. Thus, organochlorine (OC) or organophosphorus (OP) insecticides, the first generation of pesticides, are known to be highly persistent in the environment, unlike the pyrethroids that break down quickly in direct sunlight, usually just a few days after application. Nowadays, the use of OC has been banned in most developing countries because of concerns about their environmental impact and human health effects; nevertheless, their residues are still present in many environmental and biological compartments. The most important immunochemical techniques developed to analyze these compounds are listed in Table 8.7. In a recent study, we reported on how the general population is still exposed to these substances, as evidenced by the excretion of chlorophenols and bromophenols in urine.186 The study used antibodies developed for trichlorophenol,187–189 an insecticide used as a wood and textile preservative, to extract these analytes from urine and to analyze them by combining immunosorbent cartridges190 and an ELISA on a 96 setup, in such a way that 96 samples could be immunoextracted and analyzed in parallel. The results obtained from the immunochemical analyses were validated by gas chromatography-mass spectrometry (GC-MS), showing excellent correlation.186 One of the best known OC pesticides is dichloro-diphenyl-trichloroethane (DDT), and many research groups have attempted to develop antibodies to detect this compound.191,192 Beasley et al.,193 in 1998, were the first to apply a DDT ELISA to environmental samples (LOD = 0.3 mg L -1). Later, Amitarani et al.194 reported on another ELISA where DDT was detected in river water samples at levels close to 1 mg L -1. An FPIA for the detection of DDT and its isomers in drinking water was developed by Eremin et al.,195 who achieved LODs of 12 mg L -1 and 30 ng L -1, respectively. Several immunochemical analytical methods have also been developed for chlorinated cyclodienes (CCDs), such as endosulfan, heptachlor, chlordane aldrin, endrin, and dieldrin, since the pioneering work of Langone and Van Vunakis,196 who designed a RIA for dieldrin and aldrin in 1975. Manclus et al.197 produced monoclonal antibodies against endosulfan (a/b), which recognized almost all structurally related cyclodiene insecticides with good detectability. On the other hand, Stanker et al.198 adapted a commercially available ELISA kit for the analysis of endosulfan in environmental water samples with very good results. Lee and Kennedy199 produced polyclonal antibodies to develop an ELISA to detect endosulfan in runoff water and soil extracts with an LOD of 0.2 mg L -1. A direct ELISA was also developed for screening aldrin, dieldrin, and endrin compounds in tap and Nile river water samples: LODs of 5 and 10 mg L -1 were obtained for aldrin and dieldrin, respectively.200 Finally, a fiber optic immunosensor was developed, which can detect most of the cyclodiene congeners at ppb levels in soil extracts and environmental water samples, using rabbit polyclonal antibodies raised against the chlorendic caproic acid hapten.201 Several qualitative and quantitative immunochemical methods and their application to the analysis of environmental samples have been described for OP insecticides, a family that includes widely used pesticides such as azinphos-ethyl/methyl, dichlorvos, fenitrothion or fenthion, malathion, mevinphos, and parathion. Mercader and Montoya202 produced monoclonal antibodies against azinphos-methyl and developed an ELISA that was used for the analysis of water samples from different sources, reaching detectability levels near 0.05 mg L -1. Watanabe et al.203 reported the production of polyclonal antibodies and ELISA procedures to analyze fenitrothion in river, tap, and mineral water (LOD = 0.3 mg L -1). Banks et al.204 produced polyclonal antibodies against dichlorvos, an organophosphate insecticide used for stored grain, which also cross-reacts with fenitrothion. Nishi et al.205 reported the first immunoassay for malathion. Residues of this insecticide have

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TABLE 8.7 Immunochemical Techniques Developed for the Detection of Insecticides Sensitivity Target Analyte Aldrin

Technique

Matrix

LOD

ELISA

Tap and river water

Optical immunosensor

Soil and water samples

ELISA ELISA

Well, tap, channel, cistern, and drinking water Cucumber and strawberry

SPR

Ground, river, and tap water

Magneto-ELISA

Water and soil

Planar array evanescent immunosensor SPR immunosensor

Ground and river water

0.1 mg L

Drinking water

0.03 mg L-1

Deltamethrin

ELISA

River sample

Endosulfan

ELISAa

Environmental water

ELISA

Soil and runoff water

Esfenvalerate

ELISA

Tap and river water River water

Fenitrothion

Fluorescence immunoassay ELISA

Fruit extracts

ELISA

River and tap water

0.3 mg L

ELISA

Rice extracts

Fenthion

Dipstick immunoassay

Flucythrinate Malathion

Azinphos-ethyl/ methyl Carbaryl Carbofuran

Reference

IC50

200

5 mg L-1 0.05 mg L-1

0.86 mg L 5 mg L

-1

-1

5 mg L-1

201

0.33 mg L-1

202

0.13 mg L-1

396

-1

397

3.97 mg L

0.056 mg L

-1

-1

1.1 mg L

213 222

-1

1.06 mg L-1

223

17.5 mg L-1

398

2 mg well-1

198 399

0.2 mg L-1 30 mg L-1

400

0.04 mg L-1

0.8 mg L-1

233

40 ng well-1

297 ng well-1

401

6 mg L-1

402

3 mg L-1

14 mg L-1

403

Food samples

0.5 mg L-1

15 mg L-1

404

ELISA

River water and soil

10, 0.2 mg L-1

Surface water

0.50 mg L-1

0.10 mg L--1

406

Mevinphos

Sol-gel immunosorbent ELISA

Buffer

52 ng well-1

3700 mg L-1

407

Parathion

ELISA

Buffer

600 mg L-1

407

Parathionmethyl Triazophos

Commercial kit

Water

0.3 mg L-1

408

ELISA

Buffer

0.11 mg L-1

5.51 mg L-1

409

ELISA

Buffer

0.10 mg L-1

0.65 mg L-1

410

a

-1

405

Commercial kit.

been detected in ground and surface water at levels up to 6.1 mg L -1.206,207 Brun’s group208 recently developed an assay with an LOD of approximately 0.1 mg L -1 that was successfully applied to the analysis of river and groundwater samples. In contrast, monoclonal antibodies have been produced to develop an ELISA for the analysis of parathion and parathion-methyl compounds in water and milk samples at levels around 1 mg L -1.209 Similarly, a commercially available ELISA kit (EnviroGard Parathion Plate Kit) has been validated for application in water samples: LODs of 0.03 and 0.05 mg L-1 were obtained for parathion and parathion-methyl, respectively. Since their commercial introduction in the early 1960s, N-methylcarbamate pesticides (carbaryl, carbofuran (CF), methiocarb, etc.) have been used worldwide as substitutes for OCs because of their excellent efficiency as insecticides and nematicides, their relatively low mammalian toxicities in

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Analytical Measurements in Aquatic Environments

many cases, and their low bioaccumulation potentials. In recent years, several ELISAs have become commercially available or have been developed to determine these pesticides in water samples,210–215 as well as in fruits and vegetables.214,216–219 For example, the performance of two ELISA formats (microtiter plates and magnetic particles) were compared with the EPA method 531.1 (liquid chromatography-postcolumn derivatization-fluorescence detection, LC-PCR-FD) for the determination of carbaryl in groundwater samples of the Campo de Nijar aquifer (Almeria, Spain).212 A close correspondence was found for the results obtained when spiked and well water samples were split for analysis by ELISA and by LC-PCR-FD, but the absence of a matrix effect and the high throughput capability of the ELISA formats pointed to the superiority of these immunochemical methods for screening purposes. The presence of CF during a year in lake, well, and irrigation ditch water in an agricultural area south of Milan has been evaluated using a fluorescent immunoassay with a time-resolved revelation system. Results show that CF peaked at around 87 ng mL -1 in September and October.220 Another interesting approach is the homogenous immunoassay developed for CF by the same group. In this case, the determination used liposomes and a mastoparan (Mast)-hapten conjugate as cytolitic agent. Dipicolinic acid (DPA) was used as fluorescent chelating agent. Liposome lysis was proportional to the standard concentrations in a dynamic range between 10 pg and 10 ng. The assay was applied to the analysis of tap water and environmental water samples taken from the same agricultural area, with recoveries of between 90% and 105%.221 Automated methods and immunosensors have also been reported.215,220,222–227 Mauriz et al.226 described the application of a commercial optical sensor system based on SPR detection to the direct analysis of carbaryl in different environmental water samples without any sample pretreatment. Detection limits obtained for ground, river, and tap water were 1.3, 1.2, and 0.9 mg L -1, respectively, whereas the IC50 values obtained were in the 4.0–4.6 mg L -1 range. Immunochemical analytical methods have also been developed for pyrethroid insecticides. Lee et al.228,229 developed an immunoassay for analyzing pyrethroids of the second group that was applied to detect deltamethrin and bifenthrin in water and soil samples as well as deltamethrin in wheat grain. Watanabe et al.230 and Mak’s group231 developed a class-specific immunoassay for the first and second group of pyrethroids respectively, obtaining very good detection limits. A competitive ELISA has recently been developed for the detection of the pyrethroid insecticide cyhalothrin, giving an LOD of 4.7 mg L -1; it was evaluated using fortified tap water, well water, and wastewater samples with recoveries between 80% and 114%.232 Another interesting example is the fluorescence-quenching competitive immunoassay in microdroplets reported for the sensitive detection of the pyrethroid insecticide esfenvalerate using laser-induced fluorescence from a rhodamine hapten conjugate. The competitive immunoreaction was performed in microdroplets generated by a vibrating orifice aerosol generator system with a 10 mm diameter orifice. The fluorescence emitted from the droplets was detected by a 1/8 inch imaging spectrograph with a 512 × 512 thermoelectrically cooled, chargedcoupled device. A very small mass of analyte could be detected with this method; thus, monitoring of a picoliter droplet sample enabled detection down to ~0.1 nM. Matrix interferences were negligible when this technique was applied to the analysis of river water samples.233 Sasaki et al.234 developed a novel SPR biosensor chip by using a plasma-polymerized ethylene diamine film over a gold layer sputtered onto glass. Antietofenprox antibody was immobilized on the glass surface using glutaraldehyde, and the response of the SPR biosensor was compared to that of a commercial chip. The result was not so different from that obtained with the commercial chip, but the fact that the plasma polymerized membrane is optically homogeneous might have helped to produce a higher response.

8.3.2

HERBICIDES AND PLANT GROWTH REGULATORS

Herbicides are used to get rid of unwanted plants like weeds, brush, unproductive trees, and other vegetation that may deprive crops and other “useful” plants of nutrients. Numerous immunological techniques for the analysis of triazines, such as atrazine, propazine, simazine, ametryn, and cyanazine, have been developed recently (Table 8.8).185,235–237 Owing to their environmental persistence and their

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Immunochemical Analytical Methods for Monitoring the Aquatic Environment

TABLE 8.8 Immunochemical Techniques Developed for the Detection of Herbicides Sensitivity Target Analyte 2,4-D

2,4,5-T Acetochlor Atrazine

Technique

Matrix

LOD

Reference

IC50

Optical immunosensor Dipstick immunoassay ELISA

River and lake water

0.1 mg L-1

Pond water

0.5 mg L-1

Polarization fluoroimmunoassay ELISA

Drinking water

9 mg L

Soil, ground, and water

1 ng L-1

ELISA

River, lake, and tap water

ELISA

Creek and drinking water

0.2 mg L-1

ELISAa

River, estuarine, and sea water Estuarine and sea water

0.05 mg L-1

0.3 mg L-1

239

75 ng L-1 60 ng L-1

470 ng L-1 9 ng L-1

413

Drinking water

6 ng L-1

0.17 mg L-1

240

Well, river, and tap water

26 ng L-1

0.18 mg L-1

243

1.65 mg L-1

255

1.4 mg L-1

274

FIIA ELISA Amperometric immunosensor SPR immunosensor Isoproturon

Soil and water samples

249

11.6 mg L-1

246 271

5 mg L

0.14 mg L

Drinking water

40 ng L-1

Propanil

RIANA

Drinking water

Simazine

ELISA

Ground and tap water

ELISA

Lake, rain, and mineral water Ground and well water

0.6 ng L 50 ng L

238

20 ng L-1

River and estuarine water

ELISA

6 mg L-1

-1

Optical immunosensor Metsulfuron-methyl ELISA

ELISA

248

-1

-1

-1

0.01 mg L

412

52 mg L

163

-1

0.1 mg L -1

411

-1

-1

414

-1

415

2.03 mg L-1

416

0.75 mg L-1

417

1.76 mg L-1 2.09 mg L-1 2.10 mg L-1

418

0.07 mg L

Tap water Putah creek water Bay water Distilled water Groundwater Estuarine water

0.349 mg L-1 0.402 mg L-1 0.416 mg L-1

FIIA

Drinking water

0.02 mg L-1

419

Optical immunosensor Sol-gel immunosorbent m-ISLMA_1 m-ISLMA_2 m-ELISA

Drinking water

0.026 mg L-1

420

Surface water

0.25 mg L-1

0.05 mg L-1

406

Surface water

1 × 10-5 mg L-1 2 × 10-2 mg L-1 1 × 10-1 mg L-1

0.25 mg L-1 1 × 10-4 mg L-1 13.8 mg L-1

421

Mineral water

0.2 ng L-1 0.1 ng L-1

Trifluralin

m-IA m-ISLMA ELISA

Surface water

0.85 mg L-1

Linuron

ELISA (OWLS) RIANA

Surface water River and MilliQ water

Magneto-ELISA

-1

0.8 mg L 0.01 mg L-1

244 5.78 mg L-1

422

2.87 mg L-1 1.03 mg L-1

278 255

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Analytical Measurements in Aquatic Environments

water solubility (33 mg L -1), triazines are distributed mainly in groundwaters and surface waters. For this reason, a large number of reported immunoassays have focused on the analysis of natural water samples. Wittmann and Hock238 measured atrazine in drinking and groundwater samples, reaching detection limits close to 1 ng L -1 without using any preconcentration or cleanup step. The presence of atrazine has also been analyzed in estuarine and seawater samples using other immunological techniques like magneto ELISA and FIIA with very low detection limits—close to 50 ng L-1.239 Several electrochemical immunosensors have been described for atrazine detection in food and aquatic matrices, like the one presented by Zacco et al.,240 who developed an amperometric immunosensor based on modified magnetic particles with antibodies that are captured by a graphite-epoxy magneto composite, also used as the transducer for the electrical immunosensing; the LOD for drinking water samples was 6 ng L -1. Figure 8.5 shows a schematic representation of the biosensor. Several authors185,237,241 developed an impedimetric immunosensor based on interdigitated electrodes without the use of any label; this system achieved detection limits of 0.04 and 0.19 mg L -1 in buffer and wine samples, respectively. Following up the same idea, but exploring a conductometric transduction system, Valera et al.242 produced an immunosensor using antibodies labeled with gold nanoparticles; the LOD in buffer was 0.1 mg L -1. Both systems should be easily adaptable for the analysis of environmental samples. Recently, Farré et al.243 developed another immunosensor based on the SPR principle to analyze atrazine in well, river, and drinking water; detection limits were approximately 26 ng L -1 in all cases. A micro-immune-supported liquid membrane assay (μ-ISLMA) based on chemiluminescent detection has been developed to detect simazine in a single miniaturized cartridge system.244 This chapter also discusses the influence of using different SAMs and different kinds of antibodies (polyclonal, affinity purified polyclonal, and monoclonal) on extraction parameters and assay sensitivity. LODs obtained for mineral water samples were at the ng L -1 level. Tschmelak et al.163,245 applied the RIANA biosensor to detect propanil, a selective postemergent herbicide, in water samples without any pretreatment (LOD = 0.6 ng L -1). Chlorophenoxy acid herbicides are also widely used to control broadleaf weeds and grass plants. Several immunoassays have been reported for 2,4-dichlorophenoxyacetic acid (2,4-D) and 2,4,5trichlorophenoxyacetic acid (2,4,5-T).246,247 Several immunosensors have been described using a transducing principle similar to the RIANA system already described in this chapter. Thus, Meusel et al.248 reported the use of monoclonal antibodies in a sensor chip to analyze river and lake water samples, obtaining detection limits of 0.1 mg L -1. Moreover, monoclonal antibodies, produced by Cuong et al.,249 were used in a dipstick immunoassay format to analyze pond water samples. When applied to the 2,4-D compound, this semiquantitative method yielded for an IC50 of 6 mg L -1 and an LOD of 0.5 mg L -1.

(b)

Chemical reaction

(a) HRP

Wash step using a magnet

HRP

H2O H2O2 OX HRP Red Red HQ OX ne–

(c) Amperometric measures

FIGURE 8.5 Schematic representation of an electrochemical magneto immunosensing strategy for the detection of low-molecular-weight compounds. After the immunoreaction, the antibody-modified magnetic beads are captured by the m-GEC electrode. Chemical reactions occurring at the m-GEC surface polarized at -0.150 V (versus Ag/AgCl) upon the addition of H2O2 in the presence of mediator (hydroquinone) are recorded. (From Zacco, E. et al. 2006. Anal. Chem. 78: 1780–1788. With permission.)

Immunochemical Analytical Methods for Monitoring the Aquatic Environment

157

Immunochemical methods have also been reported for the analysis of phenylurea herbicides in different matrices, including food and environmental samples.250–254 Thus, recombinant antibodies have been applied to the analysis of the phenylurea herbicide diuron with very good detectability (IC50 = 2 and 12 mg L -1 in the indirect and direct ELISA formats, respectively).251 Similarly, isoproturon has been analyzed in soil extracts using an ELISA.254 An ultrasensitive time-resolved fluoroimmunoassay (TR-FIA) for diuron in water samples has been recently reported. This assay was performed using the diuron-specific polyclonal antibody raised in sheep; rabbit antisheep IgG was used as fluorescent marker, conjugated with a chelating molecule complexed with Eu3+. Even though the sensitivity of the lanthanide chelate was up to 10 times better than in other techniques, this level was 20 ng L-1 below the European Community limits. Water samples collected monthly from an agricultural area showed that peak diuron concentrations were 65 pg mL-1 in ditch water samples in June and 180 pg mL-1 in lake water samples in September.220 On the subject of immunosensors, it is worth mentioning the work by Mallat et al.,255 who again applied the RIANA system to monitor isoproturon, diuron, and linuron in Ebro delta waters (Tarragona, Spain) (LOD = 0.01 mg L -1). A flowthrough fluoroimmunosensor has also been developed for isoproturon in well water with a detectability in the mg L -1 range.256 The use of antibodies in SPE methods against phenylurea herbicides has been investigated by immobilizing the antibodies on different solid supports257–259 or encapsulating them in sol-gel matrices.260 These immunosorbents have been applied as both a cleanup and a preconcentration step of these herbicides from ground,252 drinking,259 and surface258,259 water samples, using on- and off-line procedures. Thus, with the immunosorbent conveniently packed in a C18 column coupled to a liquid chromatography (LC) system, about 10 phenylureas were monitored from the Seine River.259 The class-selectivity profile demonstrated by these immunosorbents makes them useful for multiresidue analysis procedures of this particular family of herbicides. Several immunoanalytical techniques have been developed for the analysis of chloroacetanilides, another important family of herbicides, such as alachlor,261,262 metolachlor,263–265 and their metabolites266 in various matrices. Immunoassays for detecting butachlor and acetochlor have received less attention than the above-mentioned analogs, although some immunochemical developments have also been reported.267–269 An electrochemical immunosensor270 and a fluororimmunoassay271 have also been described for acetochlor. Interesting are the interlaboratory collaborative field experiments264 carried out to compare solid-phase extraction-gas chromatography (SPE-GC), solid-phase microextraction-gas chromatography (SPME-GC), and ELISA tests for the analysis of metolachlor. Runoff water samples were collected during the first rain event following herbicide application and analyzed using different methods. Larger metolachlor concentrations were found in surface runoff (1.4–54.9 mg L -1) than in tile drainage (0.01–8.5 mg L -1). The results demonstrated that although ELISA overestimated the concentration of this chloroacetanilide herbicide, correlation with the chromatographic methods was very good. An amperometric immunosensor for acetochlor detection270 based on screen-printed electrodes has been reported, although the detectability achieved was not sufficient for the direct analysis of drinking water. The LOD described were around 25 and 60 mg L -1 for drinking and surface water, respectively. Several ELISAs have been developed for the analysis of sulfonylurea herbicides like chlorsulfuron,272 triasulfuron,273 and metsulfuron methyl.274 Schlaeppi et al.,273 for example, developed an immunoassay using monoclonal antibodies for the analysis of fortified soil samples. The sensitivity of the assay, after an optimized extraction procedure, was 0.1 pg kg-1. Eremin et al.195 developed a FPIA for chlorsulfuron detection in MilliQ water samples; the LOD obtained in 50 mL of sample was 10 mg L-1. Another example of a fluoroimmunoassay was the one developed by Wang et al.275 consisting of TR-FIA method for bensulfuron-methyl based on fluorescence resonance energy transfer (FRET) from a Tb3+ fluorescent chelate to an organic dye, Cy3 or Cy3.5; this method achieved a detection limit of 2.1 mg L-1. The same author276 developed a new immunoassay method by using graphite furnace atomic absorption spectrometry with an EDTA-Cd2+ chelate as the label; bensulfuronmethyl was analyzed using this technique (LOD = 0.95 mg L -1). Dzantiev et al.277 developed an electrochemical immunosensor for analyzing chlorsulfuron herbicide in just 15 min. The working

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Analytical Measurements in Aquatic Environments

range for the quantitative detection of chlorsulfuron was from 0.01 to 1 mg L -1. Finally, Szekacs et al.278 developed a highly sensitive immunosensor using optical waveguide lightmode spectroscopy (OWLS) to detect trifluralin, a selective pre-emergence herbicide, with an IC50 of 1.0 mg L -1. The principle is based on the precise measurement of the resonance angle of polarized laser light, diffracted by grating and coupled onto a thin waveguide.

8.4

IMMUNOCHEMICAL DETERMINATIONS OF PHARMACEUTICAL AND PERSONAL CARE PRODUCTS

The term “pharmaceutical and personal care products (PPCPs)” refers to any product used for personal health or cosmetic reasons or used in agriculture to enhance the growth or health of livestock;279 it comprises a diverse collection of thousands of chemical substances.40 The overall pharmaceutical production in Europe, Japan, and the United States amounted to USD373 billion in 2005.280 PPCPs have probably been present in the environment and water for as long as humans have been using them. While an important number of these substances enter the environment directly from industry, treated and untreated domestic sewage containing excreted PPCPs and their metabolites following human use is a major source of these compounds in the environment.39 Nowadays, sewage systems and municipal WWTPs are still not equipped for the complete removal of PPCPs or other unregulated contaminants.281 In addition to the framework provided by the Water Directive mentioned in the introduction, Directive 2001/82/EC regulates the requirements for the ecotoxicity testing of pharmaceuticals. With the advances in technologies that have improved the ability to detect, control, and quantify these chemicals, we can now begin to identify what effects, if any, these chemicals have on human and environmental health.

8.4.1 ANTIBIOTICS Antibiotics are chemical substances extremely active at low doses that kill or slow the growth of bacteria. Since their discovery, antimicrobials have been an essential part of modern human and veterinary medicine as well as in aquaculture or even in plants for the treatment of infectious diseases produced by bacteria. In the last decade, the general misuse of antibiotics as growth promoters or for prophylactic purposes282 has become a decisive factor favoring the increase of bacterial resistance. This risk situation may spread from animals to humans through the food chain8 but may also have a crucial impact on the ecosystem itself by producing adverse effects in animals and plants. At present, WWTP effluents and confined animal feeding operations (AFOs) represent the prime sources of antibiotics entering the environment:281,283 the greatest percentage of antibiotics are excreted after consumption, and thousands of tonnes of them reach the terrestrial and aquatic environment every year.1 Governmental agencies have therefore set limitations on the levels of residues in accordance with available toxicological data by laying down specific regulations or proposals that are to complement the restrictions already in place with respect to animal foods destined for human consumption. Antibiotics are classified into several families, for example, penicillins, fluoroquinolones (FQs), sulfonamides (SAs), tetracyclines (TCs), macrolides, and chloramphenicols (CAPs). In general, all these compounds are quite resistant to biodegradation since they were designed to demonstrate a certain metabolic stability during their pharmacological action; they are likely to remain in the environment in unchanged form or as persistently active metabolites.284 In this context, different techniques based on wholly divergent principles have been developed to deal with the problems relating to antibiotic residues.285–287 Most of them, like growth inhibition tests, take advantage of their antibacterial activity. Others, such as chromatographic methods, are highly specific and sensitive but require extensive sample preparation, sophisticated and therefore expensive equipment, and skilled laboratory staff. On the other hand, immunochemical techniques can be excellent tools for assessing antibiotic contamination in different environmental matrices as a result of their excellent detectability, specificity, and throughput capacities.44,287 Table 8.9 summarizes some of these techniques reported for the detection of several families of antibiotics.

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TABLE 8.9 Immunochemical Techniques Developed for the Detection of Antibiotics Sensitivity Target Analyte Sulfonamides

Sulfamethazine

Sulfamethizole Fluoroquinolones Ciprofloxacin Enrofloxacin Tetracyclines

Tetracycline Tetracycline Anhydrotetracycline Chlortetracycline Anhydrochlor-TC Oxytetracycline Chloramphenicol

Chloramphenicol CAP succinate Thiamphenicol Florefenicol Florefenicol amine Chloramphenicol Chloramphenicol CAP glucuronide Pencillin G Pencillin G Amoxicillin Tylosin Erythromycin a b c d e

Technique ELISA Charm II RIA test RIANA RIA SPIE with MALDI-TOF MS AWACSS ELISA ELISA ELISA RIA Charm II RIA test

Charm II RIA test ELISAe (IDS Corporation) ELISAe (Ridascreen) ELISAe (R-Biopharm GmH)

ELISAe (5091CAP1p, EDiagnostica) SPR Biosensor (Biacore Q) Membrane-based CL sensor TR-FIA

Matrix Fish muscle Drinking water sources Water samples Lagoon and river samples Drinking water Soil Manure River water samples Shrimp tissues Fish and shrimp sample Milk, chicken, and pork Lagoon and river samples Hog lagoon Surface water Groundwater Drinking water sources Surface and groundwater Manure samples from hog lagoons and cattle feedlots

Shrimp tissue

Prawn samples Shrimp samples Shrimp samples

SPR Biosensor (Biacore Q, sensor chip CM5)

Shrimp tissue

SPR Biosensor (Biacore Q and Qflex® Kit) RIA Fluoro immunoassay

Prawn

ELISA (IDS Corporation) ELISA (Ridascreen) RIA

LODs and IC50 calculated in buffer solution. General decision limit. Detection capacity. Linear range. Commercial kit.

Lagoon and river samples Wastewater Sewage water Surface and groundwater Lagoon and river samples

LOD (µg L-1) IC50 (µg L-1) Reference <100a 0.05 0.01 5.00 0.10 1.00 1.00 0.02 ~4.00 0.70b 5.00 1.00

0.05 0.20 0.10 0.38a 0.25a 0.01a 0.01a 0.05a 0.10 0.13b 1.00a 0.04b 3.23 0.05 0.10 0.5b 0.2b 250b 0.1b 0.04b

1.00 2.40 ~5.00 0.20 0.10 10.0

100

303 310 311 309 313

<10c 0.32a

312 323 322 324 309 348

1–20d

310 345 1.02a 5.40a 0.21a 6.92a 0.97a 0.22c

346

0.07d

336

334

339 423 0.13a 0.47a 887a 1.26a 0.07c 76% CR

30.0 58.0

337

338

309 354 345 309

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A significant number of immunochemical methods for antibiotic residue analysis with narrow or broad specificity, or even possessing multianalyte capabilities, have been described, and some of them are commercially available.39,40,287,288 We recently reported a microplate-based ELISA method that can detect 25 antibiotics from the ß-lactam (BL), SA, and FQ families.22 Moreover, the assay based on a dipstick platform is becoming the new simple, rapid and easy-to-use sensing device for on-site measurements. The biological recognition elements normally used in this user-friendly technology are the receptors;289–292 applications using antibodies have appeared in recent years254 but have so far been implemented only in the analysis of food samples, not yet in environmental samples. 8.4.1.1 Sulfonamides SAs are an important group of broad-spectrum synthetic bacteriostatic antibiotics, whose chemical structure contains a 4-aminobenzensulfonamide functional group with different heterocycles attached to the N1-position of the SA bridge. This antibiotic family is widely used in animal husbandry in most European countries.293,294 The pharmacokinetic profile of SAs ensures that they are quickly eliminated from the organism (40–90%), usually as the parent compound or as bioactive metabolites.295 As with many other pharmaceuticals, SAs are fairly water-soluble, polar compounds that ionize depending on the pH of the matrix. In addition to hydrophobic partitioning, these compounds can absorb to soils via cation exchange, cation bridging, surface complexes, and hydrogen bonding.296 Hence, SAs will persist in the environment and, because of their relatively high mobility, will enter groundwater and be transported to aquifers and surface waters;284 relevant methodologies for monitoring environmental samples are therefore necessary. Besides the large number of chromatographic methods reported,294,297–300 several immunochemical techniques have been developed for the analysis of water samples. Several ELISAs with broad301–304 or narrower selectivity profiles305–308 within the SA family have been applied to the analysis of these residues in various food matrices in compliance with legislation. Campagnolo et al.309 studied the presence of different antimicrobials in wastewater samples from pig and poultry farms using a commercial radioimmunoassay (Charm II RIA). Prior to the analysis, samples were simply filtered through a 0.45 mm glass fiber filter; an LOD of 5 mg L -1 was obtained for sulfamethazine. In order to achieve lower detection limits, Yang and Carlson310 coupled SPE cartridges to the same RIA test as a preconcentration technique. This method was optimized to detect SA and TC (see below) compounds in water samples from rivers and the influent/effluent of a WWTP. The detection limit for sulfamethazine was 0.05 mg L -1 using the SPE/RIA method; quantification of sulfamethoxazole, sulfadimethoxazone, and sulfathiazole was also possible. Initially developed for biochemical studies, RIA has the disadvantage of handling and producing radioactive residues, so their use should be avoided whenever possible. On the other hand, the already-mentioned RIANA immunosensor was used to detect SAs in drinking, ground, and surface water samples.311 With this biosensor and a mixture of antibodies, it was possible to achieve detection limits <10 ng L -1, limits of quantification (LOQ) <100 ng L -1, and IC50 values between 0.5 and 5 mg L -1 for five SAs without sample pretreatment. The automated water analyser computer supported system (AWACSS) instrument represents a development of the RIANA sensor in that the multianalyte analysis capability has been expanded, theoretically permitting simultaneous measurements of up to 30 analytes from the groups of modern pesticides, endocrine disrupting compounds, and pharmaceuticals. With this system, Tschmelak et al.184,312 achieved an LOD of <0.02 mg L -1 for sulfamethoxazole in river water samples. On the other hand, Grant et al.313 described a method for detecting residues of sulfamethazine and its major metabolite N4-acetylsulfamethazine in water, aqueous suspensions of soil, and composted manure samples, using solid-phase immunoextraction (SPIE) coupled with MALDI-TOF MS. The LODs for both compounds in all kinds of samples were <1 mg L -1. No further immunochemical methods for the direct detection of SAs in environmental samples were found; nonetheless, the application to environmental water samples of those currently applied in complex biological matrices305,314–316 is predicted to be straightforward. Several novel immunosensing strategies for detecting SAs have been developed by our group. Zacco et al.317 immobilized class-specific anti-SA antibodies to magnetic

Immunochemical Analytical Methods for Monitoring the Aquatic Environment

Electrode

161

Electrode

Insulating substrate

Interdigitated electrodes

Electrode collector bar

FIGURE 8.6 Schematic representation of a new transducer for biosensor application based on a threedimensional IDEA. Binding of molecules to the chemically modified and biofunctionalized transducer surface induces important conductivity changes between the electrodes, which can be monitored. (From Ramón-Azcón, J. et al. 2008. Biosens. Bioelectron. 23: 1367–1373. With permission.)

particles to be captured, after the immunochemical reaction, by a magneto sensor made of graphiteepoxy composite (m-GEC) that is also used as the transducer for the electrochemical detection. The LOD obtained for sulfapyridine in milk was 1.4 mg L -1. Another example, using the same immunoreagents, is presented by Bratov et al.318: a new transducer for biosensor applications based on a three-dimensional interdigitated electrode array (IDEA) with electrode digits, separated by an insulating barrier. The binding of molecules to the chemically modified surface of the transducer induces important changes in conductivity between the electrodes; impedance measurements with this immunosensor detected sulfapyridine with an IC50 of 5.6 mg L -1 in buffer. As can be seen in Figure 8.6, using this strategy, it was possible to place the immunoreaction where most of the electric field is, instead of using just a small percentage. Finally, class-selective immunoreagents for SA detection were implemented in a waveguide interrogated optical system (WIOS). The label-free sensor, developed by the Swiss Center for Electronics and Microtechnology (CSEM), is based on the evanescent wave principle, where changes in the refractive index of the modified chip surface are detected by scanning the resonance condition at which a light wave is coupled in the waveguide through a conveniently designed grating.319 Monitoring of the resonance wavelength allows real-time monitoring of the binding of nonlabeled molecules to the waveguide grating surface, previously modified with the immunoreagents by means of a photopolymerizable dextran layer. The LOD obtained with this methodology for sulfapyridine in milk was 0.5 mg L -1. 8.4.1.2 Fluoroquinolones FQs are a synthetic class of antibiotics widely used for both prevention and treatment of various diseases in animal husbandry and aquaculture, as well as in humans. The environmental concern regarding FQs is evinced not only by their potential to promote antibiotic resistance, but also by their unfavorable ecotoxicity profile.320 FQs are excreted as parent compounds, as conjugates, or as oxidation, hydroxylation, dealkylation, or decarboxylation products. FQs bind strongly to topsoils, thereby reducing the threat of surface water and groundwater contamination; this implies, however, that the terrestrial environment is a further relevant exposure pathway.40 The strong binding of FQs to soils and sediments delays their biodegradation and explains their persistence in the environment. Wastewater treatment eliminates 79–87% of FQs before their arrival in rivers; adverse effects on the

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Analytical Measurements in Aquatic Environments

aquatic habitats of surface waters are thus rather unlikely. On the other hand, these compounds are also susceptible to photodegradation in water: this involves the oxidation, dealkylation, and cleavage of the piperazine ring.321 Fluoroquinolone residues in marine products are an important analytical target because they are regarded as good indicators of environmental quality. In this context, Huet et al.322 reported the development of an ELISA for the detection of 15 fluoroquinolones in fish and shrimps, as well as in other samples (kidney, eggs, and muscle). The pretreatment required for the analysis of the marine products involved sample centrifugation and solvent extraction prior to 10-fold dilution. The assay was characterized in accordance with the recommendations of the European Commission (Commission Decision 2002/657/EC) by calculating the general decision limit (CCa) and detection capacity (CCß). CCa was calculated to be 0.70 mg L -1, whereas CCß for most of these compounds was <10 mg L -1, except in the case of sarafloxacin, oxolinic acid, flumequine, and cinoxacin, the detection capacities of which did not exceed 4, 25, 100, and 200 mg L -1, respectively. An ELISA using monoclonal antibodies with a broad specificity for fluoroquinolone antibiotics (12 FQ congeners) was described by Wang et al.323 for chicken, honey, egg, and shrimp samples: IC50 in buffer varied from 2.1 mg L -1 (norfloxacin) to 4.4 mg L -1 (lomefloxacin). Shrimp samples were fortified at different levels (50, 100, and 200 mg L -1), separately with fluoroquinolones such as enrofloxacin, ciprofloxacin, norfloxacin, ofloxacin, flumequine, and danofloxacin; recoveries were between 63% and 90%. The last example found of an immunoassay applied to the analysis of fluoroquinolones in environmental samples is the already-mentioned immunosensor developed by Campagnolo et al.;309 these authors achieved an LOD for enrofloxacin of 5.0 mg L -1. Other immunoassays performed to detect FQs in complex biological samples322,324–326 should a priori be easily adaptable for monitoring these substances in environmental water samples. The polyclonal antibodies developed and evaluated by Pinacho et al.327 have been implemented in different immunochemical techniques to analyze a wide range of fluoroquinolone congeners. The same authors developed an ELISA capable of analyzing milk samples after a very simple dilution step, obtaining detection limits for most important fluoroquinolones of <0.4 mg L -1.328 Other uses of these immunoreagents have focused on electrochemical devices.329,330 One example is an amperometric immunosensor that follows the same format as the one described in the sulfonamide section;317 with this instrument LODs of 5.3 ng L -1 for ciprofloxacin in whole milk were obtained.331 Impedance spectroscopy combined with immunosensor technology has been used to detect ciprofloxacin at 10 ng L -1 levels in buffer.332 In this approach, the sensor electrode was based on the immobilization of the antibodies by chemical binding onto a poly(pyrrole-N-hydroxysuccinimide [NHS]) film electrogenerated on a solid gold substrate. The final immunoreaction triggers a signal via impedance spectroscopy measurements. Again, the application of these new analytical approaches to environmental samples should be straightforward. 8.4.1.3 Amphenicols CAP, a bacteriostatic antimicrobial originally derived from the bacterium Streptomyces Venezuelae, was the first antibiotic to be manufactured synthetically on a large scale. Although CAP is effective against a wide variety of microorganisms, its use has been banned in the EU since 1994 because of certain toxicological side effect problems such as aplastic anemia, brown marrow suppression, or the so-called gray baby syndrome.39 For this reason, a zero tolerance was established for the presence of these residues in any kind of animal products. On the other hand, this antibiotic has been widely used in the last 10 years by many low-income Asian countries for aquaculture disease treatment, because of its exceedingly low price. Although the use of this antibiotic in animal production has recently been prohibited in these countries too, CAP residues have been detected in marine products intended for the EU market.333 According to several European Commission Decisions (2001/699/EC, 2001/705/EC, 2002/249/EC, 2002/250/EC, and 2002/251/EC), certain fishery and aquaculture products imported for human consumption must be subjected to a test in order to ensure the absence of CAP residues.334 Thus, the main efforts have focused on the study of CAP residues in marine food products to control the problems mentioned above. Impens et al.334 described the use

Immunochemical Analytical Methods for Monitoring the Aquatic Environment

163

of a commercial ELISA kit (5091CAP1p) to detect CAP in shrimp tissue after organic/aqueous extraction, obtaining an LOD of 0.1 mg L -1. The method was revalidated according to Commission Decision 2002/657/EC,335 which has been more commonly used for chromatographic techniques; CCa and CCß values of 0.13 and 0.22 mg L -1, respectively, were obtained. On the other hand, a commercial SPR immunosensor (Biacore Q) has been used by several authors to detect CAP residues in different kinds of matrices.336–338 For example, Ferguson et al.338 reported the implementation of a commercial detection kit (Qflex) in the cited biosensor to accurately determine CAP residues in milk, poultry muscle, honey, and prawn. CCa and CCß values for prawn samples, after a tedious pretreatment, were 0.04 and 0.07 mg L -1, respectively, while the glucuronide form of CAP cross-reacted 76% in this matrix. Using the same biosensor, Ashwin et al.336 obtained similar parameters for CAP detection in prawn samples but with a simpler sample pretreatment procedure. Furthermore, the immunoreagents developed by Dumont et al.337 were implemented in the same SPR sensor as described above for the simultaneous residue detection of several fenicol antibiotic congeners in shrimps from a single sample extract. The IC50 values obtained for thiamphenicol (TAP), florefenicol (FF), and CAP were 0.13, 0.47, and 1.26 mg L -1, respectively. CCß values were also estimated for each compound in this study (TAP: 0.13, FF: 0.47, and CAP: 1.26 mg L -1). In a different context, Park and Kim described the development of a membrane-based chemiluminescent immunosensor for the analysis of very low levels of CAP residues in different samples of animal food for human consumption, such as pork, beef, chicken, milk, and shrimps.339 The shrimp samples were simply filtered through Whatman paper to avoid undesirable matrix effects (LOD  3 mg L -1). Alternatively, a large number of immunoassay screening methods for CAP detection in foods (e.g., milk, eggs, and meat) and other related complex matrices have been reported in the literature.339–341 Despite the use of immunochemical methods to analyze residues in marine biota, we have not found examples of their application to analyze CAP residues in environmental samples, although these methodologies should be readily adaptable to the analysis of these types of matrices. 8.4.1.4 Tetracyclines TCs are an important group of broad-spectrum antibiotics used against Gram-negative and Grampositive microorganisms in modern human and veterinary medicine practice for both prevention and treatment of diseases, as well as additives in animal foodstuffs to promote growth in concentrated animal feeding operations (CAFOs). As with most types of antibiotics, only small portions of the tetracyclines administered are actually metabolized or absorbed in the body, and most of the drug is eliminated in feces and urine in unchanged form.342 Normally, tetracyclines are not found at high levels in the environment: because of their chelation properties, they readily precipitate in the presence of divalent cations (i.e., Ca2+, Mg2+, or Zn2+) and are accumulated in sewage sludge or sediments.343 On the other hand, tetracycline residues have also been detected in many surface water resources that receive discharges from municipal WWTPs and agricultural runoff.2,344 Besides the demonstrated persistence of TCs in agricultural soils that have received manure containing antibiotics, the biodegradation of these compounds to even more toxic substances must activate new strategies to improve their control and the efficiency of their removal in wastewater plants. To this end, a commercially available ELISA kit (RIDASCREEN®), commonly used for detecting tetracycline residues in meat and milk samples, was easily adapted for the ultratrace analysis of surface and groundwaters.345 The assay was found to be highly sensitive to tetracycline and chlortetracycline with detection limits of 0.1 mg L -1 in lake waters, runoff samples, and soil saturation extracts. Furthermore, Aga et al.346 evaluated another commercial ELISA kit (R-Biopharm GmbH) for investigating the occurrence and fate of tetracyclines in the environment. In this case, the potential use of class generic antibodies led to the multiple recognition of several TCs such as tetracycline, chlortetracycline, and oxytetracycline, and also their epimers and corresponding dehydration by-products with IC50 values from 0.2 to 6.9 mg L -1. Subsequently, the same immunochemical detection kit was evaluated by measuring the presence of tetracyclines in samples from different manured

164

Analytical Measurements in Aquatic Environments

soil surface layers (0–5 cm).347 Only trace amounts (<1 mg L -1) of oxytetracycline were recorded in these samples and none was detected in water samples from field lysimeters; tetracyclines thus have a low mobility in soil, as suggested before.342 The Charm II RIA method was applied to environmental samples but with the focus on tetracycline detection.348 This Charm II RIA, previously developed as a screening tool for detecting tetracycline residues in serum, urine, milk, and tissues, was adapted for the analysis of water samples by Meyer et al.348 who achieved an LOD of 1 mg L -1 and a semiquantitative analytical range of 1–20 mg L -1. In this study, liquid waste samples were obtained from several hog lagoons, and the surface and groundwater samples were from areas given over to intensive poultry production; the analytical results were well correlated with those acquired by means of liquid chromatography-mass spectrometry (LC-MS) techniques. The same RIA technique, again applied by Campagnolo et al.309 to different aqueous environmental samples, was able to detect chlortetracycline at sensitivity levels of 1 mg L -1. Yang and Carlson310 used SPE as a preconcentration technique in conjunction with Charm II RIA to obtain lower detection limits for tetracycline measurements in water matrices. In this case, detection limits of 0.05 mg L -1 for tetracycline, oxytetracycline, and chlortetracycline were obtained in the analysis of different wastewater samples. Other immunochemical methods developed to analyze manifold tetracycline residues, mainly in honey, milk, and animal tissues intended for human consumption,349 could be adapted to analyze water samples. 8.4.1.5 ß-Lactams The BL group is one of the most important families of antibiotics used in veterinary medicine for the treatment of septicemia, urinary infections, and pulmonary infections. The presence of penicillin residues in food of animal origin, such as milk or meat, can have the same drawbacks as other antibiotics: unfavorable microbiological effects in the dairy industry, possible hypersensitivity reactions in consumers, and antibiotic resistance.350 On the other hand, their persistence in environmental samples should be very low, mainly because of the chemically unstable BL ring, which is highly sensitive to pH, heat, and ß-lactamase enzymes.351 Some authors therefore point out the absence of this kind of antibiotic residue in water samples, but aim to detect their degradation products in order to evaluate possible future environmental risks. Several immunochemical techniques, based on different detection principles, have thus been developed to detect BL compounds in food samples of animal origin.309,352–354 Many of these technologies are applied to the analysis of milk samples, because this antibiotic family is the most frequently used for the treatment of mastitis in dairy cows. Gaudin et al.352 applied the Biacore SPR sensor, described previously for chloramphenicol detection, to detect ampicillin in milk samples using commercial monoclonal antibodies. Samples were pretreated to facilitate the opening of the BL ring; fi nal detection limits of 5.9 and 12.5 mg L -1 for ampicillin in buffer and in milk, respectively, were obtained. This immunoassay revealed high cross-reaction values for other BL antibiotics such as penicillin G and M. The same biosensor was also used by Gustavsson et al.353 to assay the activity of a carboxypeptidase and antibodies against the enzymatic product generated in milk samples. Detection limits for penicillin G were approximately 1 mg L -1, and seven BL compounds were detected below their maximum residue limits (MRLs). It can be assumed that, as in the case of the antibiotic analyses mentioned earlier, application of immunoassays originally developed for other biological samples to environmental water samples should produce even fewer matrix effects. Benito-Pena et al.354 prepared polyclonal antibodies to develop an automated flow-through fluoroimmunosensor for the analysis of penicillin antibiotics in wastewater samples from influent and effluent sewage water; LOD and IC50 values for penicillin G and amoxicillin in buffer were 2.4, 5.0, and 30, 58 mg L-1, respectively. This immunosensor was applied to the analysis of both compounds in wastewater samples passed through 0.45 mm glass fiber filters; the technique was validated by chromatography. Moreover, as in the case of SAs, fluoroquinolone, tetracycline, and chloramphenicol compounds, Campagnolo et al.309 measured BLs in water samples taken from the vicinity of a farm; they obtained a detection limit of 2 mg L -1 for pencillin G.

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Immunochemical Analytical Methods for Monitoring the Aquatic Environment

8.4.1.6 Macrolides Macrolide antibiotics, such as tylosin, roxithromycin, and erythromycin, are an important group of pharmaceuticals used in human and veterinary medical practice. Their activity stems from the presence of a large macrocyclic lactone ring containing 14, 15, or 16 atoms, with deoxy sugars, usually cladinose and desosamine, linked via glycosidic bonds. After application, a certain fraction of these macrolides is metabolized to inactive compounds, but a significant amount is excreted as active metabolites.355 Most macrolide structures enter the environment via animal manure, which limits their mobility and bioactivity. In any case, control of these residuals in the environment is necessary so as to avoid future negative impacts on public health. Kumar et al.345 reported on the detection of tylosin, used extensively in pig production for both growth promotion and therapeutic purposes, using two commercial ELISAs for surface and groundwater samples. Samples were diluted twice in buffer prior to their analysis; an LOD of 0.2 mg L -1 was obtained. Several antibiotic growth promoters, including tylosin, were analyzed in ground feed samples using a multianalyte ELISA after a cleanup step on OASIS® HLB cartridges by Situ et al.356 Polyclonal antibodies were developed for this purpose. With this method, LOD and CCß values for five banned substances in animal feeds were respectively 0.28 and 0.30 mg kg-1 for bacitracin, 1.02 and 1.50 mg kg-1 for olaquindox, 0.21 and 0.60 mg kg-1 for spiramycin/tylosin, and 0.09 and 0.20 mg kg-1 for virginiamycin. Campagnolo et al.309 measured erythromycin macrolides along with five other antibiotics, achieving RIA detection limits of around 10 mg L -1. 8.4.1.7 Other Drugs This section deals with immunochemical methods developed to determine drugs that do not belong to any of the most common antibiotic family groups described above, but because of their importance and general use require to be considered, too. Table 8.10 shows a few examples of ELISAs for the analysis of these compounds in environmental samples. A highly sensitive and specific ELISA for the determination, in different types of water samples, of diclofenac, a commonly used nonsteroidal anti-inflammatory drug (NSAID), has been developed by Deng et al.357 This analyte belongs to the most frequently detected, pharmaceutically active compounds in the water cycle. The immunoassay was able to measure tap water samples directly— respective LOD and IC50 values were 6 and 60 ng L -1. On the other hand, surface water samples required fivefold dilution and the wastewater samples 10-fold dilution in buffer to be analyzed correctly; the LODs were then 20 and 60 ng L -1, respectively. Recently, the development and validation of a highly sensitive and specific ELISA for the detection of pharmaceutical indomethacin in

TABLE 8.10 Immunochemical Techniques Developed for the Detection of Other Drugs Sensitivity Target Analyte

Technique

Matrix

LOD (µg L-1)

Diclofenac

ELISA

Tap water Surface water Wastewater

Indomethacin (acemetacin 92% CR)

ELISA

Tap water Driking water Surface water Wastewater

6 × 10-3 19 × 10-3 60 × 10-3 0.01 0.01 0.01 0.10

Nitrofurantoin

ELISA

Animal fed water

0.20

IC50 (µg L-1) 60 × 10-3

<0.25 <0.25 <0.25 <2.50 3.20

Reference 357

358

359

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Analytical Measurements in Aquatic Environments

water samples from different sites in the Chengdu area was presented by Huo et al.358 This commonly used compound is also included in the NSAID group. Although indomethacin is considered stable in the environment, its long-term presence in aquatic systems may increase chronic toxicity and more insidious effects, like endocrine disruption, growth inhibition, and cytotoxicity, in aquatic animals. The study measured tap water and drinking water samples directly (LOD = 0.01 mg L -1); the same LOD was obtained for surface water samples after these had been filtered through a 0.45 mm nylon cartridge. Wastewater samples required a 10-fold dilution step prior to analysis with the immunoassay (LOD = 0.1 mg L-1). In all cases, around 90% of acemetacin cross-reacted. Liu et al.359 prepared polyclonal antibodies for the immunochemical detection of nitrofurantoin residues in water samples. Nitrofurans are a group of synthetic broad-spectrum antibiotics frequently employed in animal production to treat and prevent gastrointestinal infections caused by Escherichia coli and Salmonella. They are also used as growth promoters in pig, poultry, and fish production. Using the relevant ELISA, LOD and IC50 values of 0.20 and 3.20 mg L -1, respectively, were obtained in drinking water fed to animals. A fluorescence-based continuous-flow immunosensor for the sensitive, precise, accurate, and fast determination of paclitaxel was developed by Sheikh and Mulchandani.360 A natural product, this compound is known to be one of the most active anticancer agents approved by FDA for application in clinical oncology practice. The assay is based on the displacement and detection downstream of rhodamine-labeled paclitaxel by a flow-through spectrofluorometer, as a result of the competition with paclitaxel introduced as a pulse into the stream of carrier buffer flowing through the system. The detection limit found in buffer and human plasma samples was around 4 mg L -1. Finally, a fluorescence immunoassay to detect spectinomycin, which is used as an oral treatment to control bacterial enteritis in pigs and to prevent and control losses due to chronic respiratory disease in chickens, was developed by Medina et al.361 The antibodies and secondary immunoreagents implemented in the assay enabled an LOD of approximately 5 mg L -1 in buffer to be obtained.

8.4.2 STEROID HORMONES Steroid hormones are a group of biologically active compounds controlling human body functions related mainly to the endocrine and immune systems. Synthesized from cholesterol, they have a cyclopenta-o-perhydrophenanthrene ring in common.40 Mammalian steroid hormones, which are secreted by the adrenal cortex, testicles, ovary, and placenta, can be classified into different groups, such as estrogens, gestagens, androgens, and glucocorticoids, depending on the intracellular receptor to which they bind in order to become active.6 Apart from the endogenous hormones, many synthetic steroids have been produced for their high bioactivity. Thus, the consumption of natural and synthetic steroids in human medicine and animal farming has increased steadily in recent decades. On the other hand, humans and animals excrete hormone steroids from their bodies, which readily enter the aquatic environment through sewage discharge and animal waste disposal, mainly via effluents from WWTPs.4,6 Once in waterways, they may adsorb to solid particles, like bed sediments or soils, where steroids may persist for long periods.362,363 The increasing number of steroid hormones in the environment may interfere with the normal functioning of endocrine systems, thus affecting reproduction and development in wildlife.363 Apart from the standard chromatographic techniques, many examples can be found in the literature of the immunochemical determination of steroid residues, mainly in biological samples, but also in environmental matrices.364,365 Table 8.11 shows some examples of the immunological methods described for these compounds. 8.4.2.1 Estrogens Estradiol is one of the main female sexual hormones; it is also the structural backbone for the engineering of some synthetic estrogens, such as ethynyl estradiol or mestranol, used in human hormone treatments. Both natural and synthetic estrogens are classified as endocrine disrupting chemicals (EDCs).6,362 Many of these substances and their metabolites end up in the environment where

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TABLE 8.11 Immunochemical Techniques Developed for the Detection of Steroid Hormones Sensitivity Target Analyte

Matrix

ELISAa (Abraxis, USA) SPEoptical sensor

Urban wastewater River and groundwater Seawater (sewage plants) Seawater

0.05 mg L-1

370

1.5 mg L-1 0.16 mg L-1

372

SPE-CLEIA

Tap and wastewater

1.5 mg L-1

TIRF

Wastewater

0.16 mg L-1

1.84 mg L-1

371

ETIA

Wastewater

0.85 mg L-1

1.2 mg L-1

371

ELISAa (Abraxis, USA) ELISAa (Abraxis, USA) TIRF

Urban wastewater River and groundwater Urban wastewater River and groundwater River water Groundwater

0.05 mg L-1

370

0.05 mg L-1

370

0.08 mg L-1 0.08 mg L-1

0.53 mg L-1 0.56 mg L-1

424

TIRF

Wastewater

0.01 mg L-1

0.51 mg L-1

371

ETIA

Wastewater

0.50 mg L-1

0.81 mg L-1

371

ELISAa (Abraxis, USA) TIRF

Urban wastewater River and groundwater Wastewater

0.05 mg L-1 0.07 mg L-1

1.07 mg L-1

371

ETIA

Wastewater

0.01 mg L-1

2.70 mg L-1

371

Noresthindrone

EIA

River and potable water

10 ng L-1

Progesterone

RIA

River and potable water

CLEIA TIRF

River and potable water MilliQ water

5 ng L-1 15 pg per tube 0.96 ng L-1

RIANA

Drinking water River water

0.2 ng L-1 0.2 ng L-1

Estradiol

Estriol Estrone

Ethynylestradiol

Testosterone

LOD

IC50

Reference

Technique

369

370

386 386 385 364 375

Notes: SPE, solid-phase extraction. a Commercial kit.

they can have adverse effects on wildlife organisms even at very low concentrations.366–368 Thus, environmental monitoring programs on estrogens call for analytical techniques capable of achieving very low detection limits. With regard to immunochemical methods, there are several commercial tests on the market, addressed mainly to food residue analysis. Nevertheless, application to the analysis of aquatic ecosystems should be easy to implement. Zhao et al.369 developed a chemiluminescence enzyme immunoassay (CLEIA) for the determination of 17b-estradiol in wastewater samples; the working linear range obtained was from 2.5 to 1600 ng L-1, with a detection limit of 1.5 ng L-1. Recoveries of spiked tap water and wastewater samples at 0, 2.5, 10, and 50 ng L-1 were in the 80–110% range. Results were compared with the commercially available radioimmunoassay kit (MARCA): a good correlation (R2 = 0.997) was obtained. Farré et al.76 evaluated four different commercially available ELISAs for the rapid screening of estrogens in different water matrices, including natural and spiked samples from urban wastewater, river water, and groundwater from the vicinity of Barcelona. ELISA kits370 were configured to measure 40 samples per plate with sufficient sensitivity, high cross-reactivity with other congeners, and reproducibility. All the samples extracted by SPE yielded recoveries from 79% to 86%; assay validation was carried out by comparison with

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Analytical Measurements in Aquatic Environments

high performance liquid chromatography tandem mass spectrometry (HPLC-MS/MS) using a triple quadrupole (QqQ) instrument. Coille et al.371 described the use of two fluorescence immunochemical methods to detect different estrogenic compounds in synthetic wastewater. In the first one, the immunosensor is based on the internal reflection fluorescence (TIRF) principle (LOD for estradiol = 0.16 mg L-1 and for estrone and ethynylestradiol = 0.07 mg L-1). The other method is an energy transfer immunoassay (ETIA), in which the specific antibody is labeled to a donor fluorescent dye, while the antigen is coupled to an acceptor dye via a bovine serum albumin (BSA) molecule. The fluorescence is quenched as a consequence of the biorecognition reaction. In this case, the respective detection limits obtained were 0.5, 0.85, and 0.01 mg L-1 for estrone, estradiol, and ethylestradiol. Recovery rates for both techniques when measuring spiked wastewater samples were between 70% and 112%. Recently, Zhang et al.372 have developed a sensitive and simple immunoassay based on the SPR technique for monitoring 17b-estradiol. Previous to their analysis, seawater samples were hydrolyzed with HCl/methanol solution and preconcentrated using C18 SPE; recovery values were approximately 92%. Subsequent studies showed that the precision and repeatability of the SPR assay were good; cross-reactivity with other estrogens was very low. 8.4.2.2 Androgens The main applications of immunochemical techniques for androgens are in the doping control of athletes, forensic chemistry, farm animals for human consumption, and food analysis.373,374 However, there have been a few applications in the environmental field for natural or synthetic androgens. For example, Barel-Cohen et al.4 monitored natural steroids in sewage and fishpond effluents, finding levels of testosterone between 2.1 and 7.8 ng L-1 at different collecting points along a river. A TIRF immunosensor has been developed for reliable sub-ng L-1 detection of testosterone in aquatic environmental matrices without sample pretreatment. Thus, direct analysis of spiked lab water, drinking water, and river water samples gave an LOD of 0.2 ng L-1 with recovery rates between 70% and 120%.375 This sensor system was therefore shown to be a suitable warning tool in environmental analysis, in addition to the standard analytical methods. On the other hand, several ELISA procedures have been developed for the analysis of testosterone and related compounds in biological samples.365,376 In the case of performance-enhancing anabolic steroids, such as stanozolol, nandrolone, and the recently designed steroid known as tetrahydrogestrinone, immunochemical assays have also been performed on equine and human urine samples during doping controls.377–379 Additionally, powerful techniques combining multiresidue immunoaffinity chromatography with GC-MS or ELISAs are available for the simultaneous identification and semiquantification of various androgens in samples of urine and feces.39,378,379 Figure 8.7 shows a scheme of a multi-immunoaffinity chromatography (multi-IAC) procedure. Immunosensors have made a great contribution in the field of androgenic steroid detection, giving detection limits comparable to those obtained with standard ELISA procedures. Several electrochemical immunosensors have been developed for detecting testosterone, methyltestosterone,

Sample Multi-immunoaffinity column A. Loading sample: Specific binding of target analytes B. Washing step: Interference compounds are removed C. Elution step: Specific elution conditions to dissociate the analytes

Sample purified

FIGURE 8.7 purification.

Analysis

Schematic sequential step procedure for chromatographic determination after multi-IAC

Immunochemical Analytical Methods for Monitoring the Aquatic Environment

169

19-nortestosterone, boldenone, and methylboldenone in spiked bovine urine using screen-printed electrodes.380–382 Once again, the techniques already used to analyze these compounds in complex biological matrices can be adapted for the analysis of environmental samples. 8.4.2.3 Gestagens Gestagens are hormones that produce similar effects to those of endogenous progesterone, which is excreted from the ovary to act as a balancer in the menstrual cycle, pregnancy, and embryogenesis. As with estrogens, most of the immunochemical techniques described in the literature have been developed to analyze these compounds in biological matrices.383–385 On the other hand, Aherne et al. described a RIA for progesterone and norethindrone detection in water samples, obtaining LODs of 6 and 17 ng L -1, respectively.386 This group also reported that norethindrone underwent 28% biodegradation in an activated sludge system in 6 h and was completely degraded in one day, which is the time required to purify river water for drinking purposes. Furthermore, Käppel et al.364 developed an immunosensor based on TIRF detection to analyze progesterone in spiked MilliQ water. The assay was optimized to obtain results in 5 min with an LOD of 0.96 ng L -1. All these results show fairly well the usefulness of immunochemical techniques for the determination of micro- and nanogram per liter quantities of gestagens in aqueous samples.387 8.4.2.4 Corticosteroids Endogenous corticosteroids are produced by the adrenal glands in response to stressors such as exercise, illness, and starvation.5 Synthetic cortisone derivatives were synthesized in the late 1940s for therapeutic purposes. Lately, these products have found their way into the world of sports because of their anti-inflammatory properties, but they are now on the list of substances banned by the International Olympic Committee (IOC). Moreover, corticosteroids like dexamethasone are used not only in veterinary practice for the treatment of respiratory and gastrointestinal disorders, but also as illegal growth promoters in animal feedstuffs. To control this undesirable situation, efficient screening procedures, based mainly on ELISA methods, have been described for the analysis of most important corticosteroids in biological matrices,388–390 but they have not yet been applied to environmental samples. Pujos390 reported the analysis of 18 human corticosteroids, both endogenous and synthetic, in spiked urine samples. The samples required a pretreatment based on simple 1/50 dilution. ELISA is a suitable technique for the systematic detection of corticosteroids by the food and agriculture industries in many different sample matrices;391–393 their implementation in the analysis of aquatic environmental samples seems appropriate.

8.5

GENERAL SUMMARY

In recent decades, immunochemical techniques have been widely demonstrated to be an interesting alternative to the more conventional analytical methodologies in many areas, but additional work is still necessary to completely adapt them to the analysis of environmental contaminants. On the other hand, considering that the analysis of very complex biological samples with these methods has been successful, the prospects for their application to the analysis of water and soil samples seem highly promising. In this relatively new situation, where data on the occurrence, risk assessment, and environmental toxicity of most of these emerging pollutants are not available, collaboration and interchange of expertise between analytical and immunochemists are needed to achieve this objective. The benefits accruing from these methods (i.e., high sensitivity, selectivity, cost-effectiveness, high sample processing capabilities vis-à-vis target analytes) are nowadays available for assessing risk and protecting public health from the adverse effects of these types of pollutants. From now on, research efforts should focus on the development of multianalyte immunochemical systems, in which more than one compound or group of compounds can be detected simultaneously, and on the design of new analytical user-friendly devices (i.e., immunosensors) for continuous or on-site measurements. Technical development should be accompanied by some officially organized efforts

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to find ways of validating screening immunoassay techniques and recognizing them as practicable routine methods in environmental monitoring laboratories. For the time being, directives are issued, regulations enacted, and conferences held to ensure water quality, protect water resources, and ensure the good health of the entire environment.

ACKNOWLEDGMENTS This work has been supported by the Ministry of Science and Technology (Contract numbers AGL2005-07700-C06-01, NAN2004-09195-C04-04, and NAN2004-09415-C05-02). The AMR group is a Group de Recerca de la Generalitat de Catalunya and has support from the Departament d’Universitats, Recerca i Societat de la Informació de la Generalitat de Catalunya (expedient 2005SGR 00207).

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338. Ferguson, J., A. Baxter, P. Young, et al. 2005. Detection of chloramphenicol and chloramphenicol glucuronide residues in poultry muscle, honey, prawn and milk using a surface plasmon resonance biosensor and Qflex(R) kit chloramphenicol. Anal. Chim. Acta 529: 109–113. 339. Park, I.-S. and N. Kim. 2006. Development of a chemiluminescent immunosensor for chloramphenicol. Anal. Chim. Acta 578: 19–24. 340. Scortichini, G., L. Annunziata, M.N. Haouet, et al. 2005. ELISA qualitative screening of chloramphenicol in muscle, eggs, honey and milk: Method validation according to the Commission Decision 2002/657/ EC criteria. Anal. Chim. Acta 535: 43–48. 341. Zhang, S., Z. Zhang, W. Shi, et al. 2006. Development of a chemiluminescent ELISA for determining chloramphenicol in chicken muscle. J. Agric. Food Chem. 54: 5718–5722. 342. Kim, S., P. Eichhorn, J.N. Jensen, et al. 2005. Removal of antibiotics in wastewater: Effect of hydraulic and solid retention times on the fate of tetracycline in the activated sludge process. Environ. Sci. Technol. 39: 5816–5823. 343. Nelson, M., W. Hillen, and R.A. Greenwald. 2001. Tetracyclines in Biology, Chemistry and Medicine. Birkhäuser: Springer. 344. Hirsch, R., T. Ternes, K. Haberer, et al. 1999. Occurrence of antibiotics in the aquatic environment. Sci. Total Environ. 225: 109–118. 345. Kumar, K., A. Thompson, A.K. Singh, et al. 2004. Enzyme-linked immunosorbent assay for ultratrace determination of antibiotics in aqueous samples. J. Environ. Qual. 33: 250–256. 346. Aga, D.S., R. Goldfish, and P. Kulshrestha. 2003. Application of ELISA in determining the fate of tetracyclines in land-applied livestock wastes. Analyst 128: 658–662. 347. Aga, D.S., S. O’Connor, S. Ensley, et al. 2005. Determination of the persistence of tetracycline antibiotics and their degradates in manure-amended soil using enzyme-linked immunosorbent assay and liquid chromatography-mass spectrometry. J. Agric. Food Chem. 53: 7165–7171. 348. Meyer, M.T., J.E. Bumgarner, J.L. Varns, et al. 2000. Use of radioimmunoassay as a screen for antibiotics in confined animal feeding operations and confirmation by liquid chromatography/mass spectrometry. Sci. Total Environ. 248: 181–187. 349. Pastor-Navarro, N., S. Morais, A. Maquieira, et al. 2007. Synthesis of haptens and development of a sensitive immunoassay for tetracycline residues: Application to honey samples. Anal. Chim. Acta 594: 211–218. 350. Beausse, J. 2004. Selected drugs in solid matrices: A review of environmental determination, occurrence and properties of principal substances. Trends Anal. Chem. 23: 753–761. 351. Li, D., M. Yang, J. Hu, et al. 2008. Determination of penicillin G and its degradation products in a penicillin production wastewater treatment plant and the receiving river. Water Res. 42: 307–317. 352. Gaudin, V., J. Fontaine, and P. Maris. 2001. Screening of penicillin residues in milk by a surface plasmon resonance-based biosensor assay: Comparison of chemical and enzymatic sample pre-treatment. Anal. Chim. Acta 436: 191–198. 353. Gustavsson, E., J. Degelaen, P. Bjurling, et al. 2004. Determination of b-lactams in milk using a surface plasmon resonance-based biosensor. J. Agric. Food Chem. 52: 2791–2796. 354. Benito-Pena, E., M.C. Moreno-Bondi, G. Orellana, et al. 2005. Development of a novel and automated fluorescent immunoassay for the analysis of b-lactam antibiotics. J. Agric. Food Chem. 53: 6635–6642. 355. Yang, S. and K.H. Carlson. 2004. Solid-phase extraction-high-performance liquid chromatography-ion trap mass spectrometry for analysis of trace concentrations of macrolide antibiotics in natural and waste water matrices. J. Chromatogr. A 1038: 141–155. 356. Situ, C. and C.T. Elliott. 2005. Simultaneous and rapid detection of five banned antibiotic growth promoters by immunoassay. Anal. Chim. Acta 529: 89–96. 357. Deng, A., M. Himmelsbach, Q.Z. Zhu, et al. 2003. Residue analysis of the pharmaceutical diclofenac in different water types using ELISA and GC-MS. Environ. Sci. Technol. 37: 3422–3429. 358. Huo, S.-M., H. Yang, and A.-P. Deng. 2007. Development and validation of a highly sensitive ELISA for the determination of pharmaceutical indomethacin in water samples. Talanta 73: 380–386. 359. Liu, W., C. Zhao, Y. Zhang, et al. 2007. Preparation of polyclonal antibodies to a derivative of 1-aminohydantoin (AHD) and development of an indirect competitive ELISA for the detection of nitrofurantoin residue in water. J. Agric. Food Chem. 55: 6829–6834. 360. Sheikh, S.H. and A. Mulchandani. 2001. Continuous-flow fluoro-immunosensor for paclitaxel measurement. Biosens. Bioelectron. 16: 647–652. 361. Medina, M.B. 2004. Development of a fluorescent latex immunoassay for detection of a spectinomycin antibiotic. J. Agric. Food Chem. 52: 3231–3236.

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362. Kuster, M., M. Jose Lopez de Alda, and D. Barcelo. 2004. Analysis and distribution of estrogens and progestogens in sewage sludge, soils and sediments. Trends Anal. Chem. 23: 790–798. 363. Desbrow, C., E.J. Routledge, G.C. Brighty, et al. 1998. Identification of estrogenic chemicals in STW effluent. 1. Chemical fractionation and in vitro biological screening. Environ. Sci. Technol. 32: 1549–1558. 364. Käppel, N.D., F. Proll, and G. Gauglitz. 2007. Development of a TIRF-based biosensor for sensitive detection of progesterone in bovine milk. Biosens. Bioelectron. 22: 2295–2300. 365. Lu, H., G. Conneely, M.A. Crowe, et al. 2006. Screening for testosterone, methyltestosterone, 19-nortestosterone residues and their metabolites in bovine urine with enzyme-linked immunosorbent assay (ELISA). Anal. Chim. Acta 570: 116–123. 366. Hansen, P.D., H. Dizer, B. Hock, et al. 1998. Vitellogenin—a biomarker for endocrine disruptors. Trends Anal. Chem. 17: 448–451. 367. Pelissero, C., G. Flouriot, J.L. Foucher, et al. 1993. Vitellogenin synthesis in cultured hepatocytes; an in vitro test for the estrogenic potency of chemicals. J. Steroid Biochem. Mol. Biol. 44: 263–272. 368. Purdom, C.E., P.A. Hardiman, V.V.J. Bye, et al. 1994. Estrogenic effects of effluents from sewage treatment works. Chem. Ecology 8: 275–285. 369. Zhao, L., J.-M. Lin, Z. Li, et al. 2006. Development of a highly sensitive, second antibody format chemiluminescence enzyme immunoassay for the determination of 17[beta]-estradiol in wastewater. Anal. Chim. Acta 558: 290–295. 370. Farré, M. 2006. Evaluation of commercial immunoassays for the detection of estrogens in water by comparison with high-performance liquid chromatography tandem mass spectrometry HPLC–MS/MS (QqQ). Anal. Bioanal. Chem. 385: 1001. 371. Coille, I., S. Reder, S. Bucher, et al. 2002. Comparison of two fluorescence immunoassay methods for the detection of endocrine disrupting chemicals in water. Biomol. Eng. 18: 273–280. 372. Zhang, W.-W., Y.-C. Chen, Z.-F. Luo, et al. 2007. Analysis of 17[beta]-estradiol from sewage in coastal marine environment by surface plasmon resonance technique. Chem. Res. Chinese Univers. 23: 404–407. 373. Kazlauskas, R. 2000. Drugs in sports: Analytical trends. Ther. Drug Monit. 22: 103–109. 374. Ueki, M. and M. Okano. 1999. Doping with naturally occurring steroids. J. Toxicol. Toxin. Rev. 18: 177–195. 375. Tschmelak, J., M. Kumpf, N. Kappel, et al. 2006. Total internal reflectance fluorescence (TIRF) biosensor for environmental monitoring of testosterone with commercially available immunochemistry: Antibody characterization, assay development and real sample measurements. Talanta 69: 343–350. 376. Degand, G., P. Schmitz, and G. Maghuin-Rogister. 1989. Enzyme immunoassay screening procedure for the synthetic anabolic estrogens and androgens diethylstilbestrol, nortestosterone, methyltestosterone and trenbolone in bovine urine. J. Chromatogr. B 489: 235–243. 377. Salvador, J.P., F. Sanchez-Baeza, and M.P. Marco 2007. Preparation of antibodies for the designer steroid tetrahydrogestrinone and development of an Enzyme-Linked Immunosorbent Assay for human urine analysis. Anal. Chem. 79: 3734–3740. 378. Salvador, J.P., F. Sanchez-Baeza, and M.P. Marco. 2008. Simultaneous immunochemical detection of stanozolol and the main human metabolite, 3’-hydroxy-stanozolol, in urine and serum samples. Anal. Biochem. 376: 221–228. 379. Tang, P.W., D.L. Crone, C.S. Chu, et al. 1993. Measuring the nandrolone threshold ratio by enzymelinked immunosorbent assay for 5[alpha]-estrane-3[beta],17[alpha]-diol. Anal. Chim. Acta 275: 139–146. 380. Conneely, G., M. Aherne, H. Lu, et al. 2007. Electrochemical immunosensors for the detection of 19-nortestosterone and methyltestosterone in bovine urine. Sens. Actuat. B: Chem. 121: 103–112. 381. Conneely, G., M. Aherne, H. Lu, et al. 2007. Development of an immunosensor for the detection of testosterone in bovine urine. Anal. Chim. Acta 583: 153–160. 382. Lu, H., G. Conneely, M. Pravda, et al. 2006. Screening of boldenone and methylboldenone in bovine urine using disposable electrochemical immunosensors. Steroids 71: 760–767. 383. Corrie, J.E.T., W.A. Ratcliffe, and J.S. Macpherson. 1981. Generally applicable 125 iodine-based radioimmunoassays for plasma progesterone. Steroids 38: 709–717. 384. Elder, P.A., K.H.J. Yeo, J.G. Lewis, et al. 1987. An enzyme-linked immunosorbent assay (ELISA) for plasma progesterone: Immobilised antigen approach. Clin. Chim. Acta 162: 199–206. 385. Kohen, F., J.B. Kim, H.R. Lindner, et al. 1981. Development of a solid-phase chemiluminescence immunoassay for plasma progesterone. Steroids 38: 73–88.

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386. Aherne, G.W., J. English, and V. Marks. 1985. The role of immunoassay in the analysis of microcontaminants in water samples. Ecotoxicol. Environ. Saf. 9: 79–83. 387. Carralero, V., A. Gonzalez-Cortes, P. Yanez-Sedeno, et al. 2007. Nanostructured progesterone immunosensor using a tyrosinase-colloidal gold-graphite-Teflon biosensor as amperometric transducer. Anal. Chim. Acta 596: 86–91. 388. Roberts, C.J. and L.S. Jackson. 1995. Development of an ELISA using a universal method of enzymelabelling drug-specific antibodies Part I: Detection of dexamethasone in equine urine. J. Immunol. Methods 181: 157–166. 389. Anfossi, L., C. Tozzi, C. Giovannoli, et al. 2002. Development of a non-competitive immunoassay for cortisol and its application to the analysis of saliva. Anal. Chim. Acta 468: 315–321. 390. Pujos, E. 2005. Comparison of the analysis of corticosteroids using different techniques. Anal. Bioanal. Chem. 381: 244–254. 391. Brambilla, G., M. Fiori, and E. Pierdominici. 1998. A possible correlation between the blood leukocyte formula and the use of glucocorticoids as growth promoters in beef cattle. Veterin. Res. Commun. 22: 457–465. 392. Delahaut, P., P. Jacquemin, Y. Colemonts, et al. 1997. Quantitative determination of several synthetic corticosteriods by gas chromatography-mass spectrometry after purification by immunoaffinity chromatography. J. Chromatogr. B 696: 203–215. 393. Brunn, H. 1994. Identification and quantification of dexamethasone and related xenobiotic corticosteroids in cattle urine with ELISA and HPLC/ELISA. Archiv Lebensmittelhyg 45: 96. 394. Sanchez-Martinez, M.L., M.P. Aguilar-Caballos, S.A. Eremin, et al. 2007. Long-wavelength fluorescence polarization immunoassay for surfactant determination. Talanta 72: 243–248. 395. Carlson, L., B. Holmquist, R. Ladd, et al. 1996. Immunoassay for mercury in seafood and animal tissues. In: R.C. Beier and L.H. Stanker (eds), Immunoassays for Residue Analysis, pp. 388–394. Oxford: Oxford University Press. 396. Abad, A., M.J. Moreno, and A. Montoya. 1999. Development of monoclonal antibody-based immunoassays to the N-methylcarbamate pesticide carbofuran. J. Agric. Food Chem. 47: 2475–2485. 397. Mauriz, E., A. Calle, J.J. Manclus, et al. 2006. Single and multi-analyte surface plasmon resonance assays for simultaneous detection of cholinesterase inhibiting pesticides. Sens. Actuat. B: Chem. 118: 399–407. 398. Lee, H.J., G. Shan, T. Watanabe, et al. 2002. Enzyme-linked immunosorbent assay for the pyrethroid deltamethrin. J. Agric. Food Chem. 50: 5526–5532. 399. Lee, N.J., H.L. Beasley, S.W.L. Kimber, et al. 1997. Application of immunoassays to studies of the environmental fate of endosulfan. J. Agric. Food Chem. 45: 4147–4155. 400. Shan, G.M., D.W. Stoutamire, I. Wengatz, et al. 1999. Development of an immunoassay for the pyrethroid insecticide esfenvalerate. J. Agric. Food Chem. 47: 2145–2155. 401. Garrett, S.D., D.J.A. Appleford, G.M. Wyatt, et al. 1997. Production of a recombinant anti-parathion antibody (scFv); stability in methanolic food extracts and comparison to an anti-parathion monoclonal antibody. J. Agric. Food Chem. 45: 4183–4189. 402. Watanabe, E., Y. Kanzaki, H. Tokumoto, et al. 2002. Enzyme-linked immunosorbent assay based on a polyclonal antibody for the detection of the insecticide fenitrothion. Evaluation of antiserum and application to the analysis of water samples. J. Agric. Food Chem. 50: 53–58. 403. Kim, Y.J., Y.A. Kim, Y.T. Lee, et al. 2007. Enzyme-linked immunosorbent assays for the insecticide fenitrothion—influence of hapten conformation and sample matrix on assay performance. Anal. Chim. Acta 591: 183–190. 404. Cho, Y.A., Y.J. Kim, B.D. Hammock, et al. 2003. Development of a microtiter plate ELISA and a dipstick ELISA for the determination of the organophosphorus insecticide fenthion. J. Agric. Food Chem. 51: 7854–7860. 405. Nakata, M., A. Fukushima, and H. Ohkawa. 2001. A monoclonal antibody-based ELISA for the analysis of the insecticide flucythrinate in environmental and crop samples. Pest. Manage. Sci. 57: 269–277. 406. Vera-Avila, L.E., J.C. Vazquez-Lira, M.G. De Llasera, et al. 2005. Sol-gel immunosorbents doped with polyclonal antibodies for the selective extraction of malathion and triazines from aqueous samples. Environ. Sci. Technol. 39: 5421–5426. 407. Alcocer, M.J.C., P.P. Dillon, B.M. Manning, et al. 2000. Use of phosphonic acid as a generic hapten in the production of broad specificity anti-organophosphate pesticide antibody. J. Agric. Food Chem. 48: 2228–2233. 408. Hennion, M.-C. and D. Barceló. 1998. Strengths and limitations of immunoassays for effective and efficient use for pesticide analysis in water samples: A review. Anal. Chim. Acta 362: 3–34.

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409. Liu, S.H., L. Wang, and L.H. Wei. 2005. Studies on the immunoassay for triazophos. Chin. J. Anal. Chem. 33: 1697–1700. 410. Gui, W.J., R.Y. Jin, Z.L. Chen, et al. 2006. Hapten synthesis for enzyme-linked immunoassay of the insecticide triazophos. Anal. Biochem. 357: 9–14. 411. Karu, A.E., R.O. Harrison, D.J. Schmidt, et al. 1991. Monoclonal immunoassay of triazine herbicides— development and implementation. ACS Symp. Ser. 451: 59–77. 412. Bushway, R.J., L.B. Perkins, L. Fukal, et al. 1991. Comparison of enzyme-linked-immunosorbent-assay and high-performance liquid-chromatography for the analysis of atrazine in water from Czechoslovakia. Archiv. Environ. Contam. Toxicol. 21: 365–370. 413. Gascon, J., A. Oubina, B. Ballesteros, et al. 1997. Development of a highly sensitive enzyme-linked immunosorbent assay for atrazine—performance evaluation by flow injection immunoassay. Anal. Chim. Acta 347: 149–162. 414. Wortberg, M., M.H. Goodrow, S.J. Gee, et al. 1996. Immunoassay for simazine and atrazine with low cross-reactivity for propazine. J. Agric. Food Chem. 44: 2210–2219. 415. Winklmair, M., M.G. Weller, J. Mangler, et al. 1997. Development of a highly sensitive enzyme-immunoassay for the determination of triazine herbicides. Fresenius J. Anal. Chem. 358: 614–622. 416. Brena, B.M., L. Arellano, C. Rufo, et al. 2005. ELISA as an affordable methodology for monitoring groundwater contamination by pesticides in low-income countries. Environ. Sci. Technol. 39: 3896–3903. 417. Schneider, P. and B.D. Hammock. 1992. Influence of the ELISA format and the hapten enzyme conjugate on the sensitivity of an immunoassay for S-triazine herbicides using monoclonal-antibodies. J. Agric. Food Chem. 40: 525–530. 418. Gascon, J., E. Martinez, and D. Barcelo. 1995. Determination of atrazine and alachlor in natural-waters by a rapid-magnetic particle-based elisa—influence of common cross-reactants—deethylatrazine, deisopropylatrazine, simazine and metolachlor. Anal. Chim. Acta 311: 357–364. 419. Kramer, P. and R. Schmid. 1991. Flow-Injection Immunoanalysis (FIIA)—a new immunoassay format for the determination of pesticides in water. Biosens. Bioelectron. 6: 239–243. 420. Klotz, A., A. Brecht, C. Barzen, et al. 1998. Immunofluorescence sensor for water analysis. Sens. Actuat. B: Chem. 51: 181–187. 421. Tudorache, M., M. Co, H. Lifgren, et al. 2005. Ultrasensitive magnetic particle-based immunosupported liquid membrane assay. Anal. Chem. 77: 7156–7162. 422. Hegedus, G., I. Belai, and A. Szekacs. 2000. Development of an enzyme-linked immunosorbent assay (ELISA) for the herbicide trifluralin. Anal. Chim. Acta 421: 121–133. 423. Shen, J., Z. Zhang, Y. Yao, et al. 2006. A monoclonal antibody-based time-resolved fluoroimmunoassay for chloramphenicol in shrimp and chicken muscle. Anal. Chim. Acta 575: 262–266. 424. Rodriguez-Mozaz, S., M.J.L. de Alda, and D. Barcelo. 2006. Fast and simultaneous monitoring of organic pollutants in a drinking water treatment plant by a multi-analyte biosensor followed by LC-MS validation. Talanta 69: 377–384.

9

Application of Biotests Lidia Wolska, Agnieszka Kochanowska, and Jacek Namies´nik

CONTENTS 9.1 9.2 9.3

Introduction ...................................................................................................................... Chemical Monitoring in Assessing the Extent of Environmental Pollution .................... Importance of Toxicity Tests ............................................................................................ 9.3.1 Toxkit Tests ........................................................................................................... 9.4 Integrated System of Water Pollution Assessment ........................................................... 9.5 Legal Regulations Applying to the Use of Bioassays in Environmental Monitoring ...... 9.6 Ecotoxicological Classification of Environmental Samples ............................................. 9.7 Bioassay Application in Environmental Monitoring: Some Case Studies ....................... 9.7.1 Identification of Toxic Compounds ....................................................................... 9.7.2 Identification of Hot Spots (Sites with a Very High Level of Pollution) .............. 9.7.3 Ranking of Problems in Polluted Areas Managed by Specific Authorities ......... 9.7.4 Revision of Monitoring Parameters ...................................................................... 9.8 Conclusions ....................................................................................................................... References ..................................................................................................................................

189 190 192 195 200 201 201 210 210 211 212 214 216 216

9.1 INTRODUCTION Rapid developments of new technologies, progressive urbanization, and consumer lifestyles cause adverse and sometimes even irreversible changes in the environment. Air, water, and soil are exposed to large-scale pollution, originating mostly from anthropogenic sources. The pollution present in the abiotic part of the environment is subject to the following processes: • Transport, which causes it to occur in places distant from emission sources. • Physical and chemical changes (photochemical and biochemical) responsible for the production of new compounds (secondary pollution), and a decrease in the concentration of primary pollution. From the abiotic part of the environment, chemical compounds permeate into plant, animal, and human organisms. Living organisms function in an integrated network of connections between themselves and their surroundings. A stable exchange of matter, energy, and information takes place between the elements of the networks, and the correct functioning of all the elements is possible only in a state of mutual dynamic equilibrium, that is, homeostasis. Changes in the environment disrupt this equilibrium and if far-reaching, often cause irreversible damage to individual species or entire ecosystems. At the beginning of the 1970s, increasing environmental awareness regarding the influence of toxic substances resulted in the emergence of many nongovernmental organizations; in cooperation with government departments they established systems for monitoring and reducing pollution.

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In the early days of these systems, monitoring was based mostly on chemical parameters, both total and individual. General criteria for the selection of these parameters resulted from the then state of knowledge about the presence of toxic compounds in the environment and included the toxicity of substances and the scale of their occurrence in the environment. Along with an increasing recognition of the network relationships occurring in ecosystems and the identification of new environmental toxins, the list of monitored substances gradually grew. At present, according to the Water Directive, some 170 substances need to be monitored in aquatic environments (including 33 priority compounds), and new substances are waiting to be added to the list.1 Gathering information about the environment is significantly hampered by • The presence of thousands of substances (with well-known or unknown toxic properties), which have not been detected by monitoring. • The bioavailability of toxic substances, which is not identical to their total content in individual compartments of the environment. • Synergetic effects, the estimation of which has too great a risk of error in such a complex system as environmental samples. Information based on chemical monitoring records alone is difficult to convert into specific knowledge about any real threat to living organisms in a given compartment of the environment caused by the presence in it of toxic substances. This is a consequence of a basic fault in the present system, namely, the impossibility of indicating the potential toxic effects on the investigated ecosystem of a diverse (with regard to the kinds of pollutants and their concentrations) mixture of compounds. The question then arises: How is it possible to accurately quantify the threat associated with such a complex mixture of pollutants present in the environment?

9.2 CHEMICAL MONITORING IN ASSESSING THE EXTENT OF ENVIRONMENTAL POLLUTION At present, the monitoring of aquatic environments across the European Union (EU) is administered by the Water Framework Directive (WFD) and its daughter directives, which oblige EU member states to improve the status of the waters in their river basins and maintain them in “good status” by 2015.1 Within the framework of a “management by river basin” system, the member states establish surveillance and operational monitoring. Surveillance monitoring is conducted to obtain information on long-term changes in the natural conditions prevalent in a given area, or changes resulting from widespread anthropogenic activity. When there is a risk of the environmental objectives for the waters in a given river basin not being fulfilled, operational monitoring is applied. In some cases, it is necessary to invoke investigative monitoring, the aim then being to determine why the waters in a particular area do not meet environmental objectives. Each of the three kinds of monitoring requires appropriate tools to obtain significant and reliable information for effective water management. Although the WFD does not include recommendations concerning specific monitoring methods, it is self-evident that their selection should allow for costs and the applicability of a given method. The achievement of WFD objectives, however, also depends on the availability of suitable tools and technologies. According to Annex V of the WFD, surface water monitoring should include the following indicative parameters of water quality elements1: • Biological • Hydromorphological • Chemical and physicochemical The hydromorphological quality elements include the dynamics of water flow, the size of the investigated water district, and the structure and composition of the ground. The biological quality

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elements include the species composition and population sizes of organisms living in a given aquatic ecosystem (flora, benthic invertebrates, and ichthyofauna). The changes in the composition and numbers of organisms ensuing from environmental pollution (biological, chemical, or physical) appear after a certain time lag (often after many months or years) and therefore relate to the existing effects of pollution. As such, this information cannot result in either an efficient and effective program for future monitoring or preventive actions within operational monitoring. Annex V in the WFD describes the framework for groundwater monitoring; it specifies monitoring of the quantitative status (by measuring the groundwater level) and chemical status. Until quite recently, chemical monitoring relied exclusively on determining the concentrations of certain chemical compounds (selected as indicators of chemical environmental pollution) in water samples, sediments, or soils using classical analytical methods. From a theoretical point of view, the best use of the appropriate analytical methods would be to provide a full analytical characterization of the environment, that is, to determine the concentrations of all known and unknown pollutants in each of its compartments. However, it is doubtful whether such a task is possible or even relevant, bearing in mind • • • • •

The number of compounds which should be determined The diversity of concentrations (mostly trace and microtrace) The fluctuations of pollutant concentrations over time and in a given area The complex composition of sample matrices The complicated and therefore time-consuming and labor-intensive procedures of preparing samples for analysis • The additional stress on the environment resulting from the use of chemical reagents, primarily organic solvents used in sample preparation • The additional costs involved in the purchase of high-purity reagents, and the necessity to use an excess of reagents • The problems with obtaining suitable reference materials necessary for the validation of analytical methods and the calibration of measuring and control instruments Classical analytical methods also have other limitations. Measurement data cannot be a source of information about possible interactions of toxic substances because2 • Toxic effects are summed (additive synergism) • The overall toxic effect is significantly greater than that resulting from the simple summation of the effects of the individual components (hyperadditive synergism) • The effects of chemical compounds may weaken and even cancel each other out (antagonism) In practice, the classical analytical methods used to assess the degree of environmental pollution are intended for the determination of only a limited number of chemical compounds (or groups of compounds), that is, those whose presence in the environment and permitted levels of concentration are regulated for environmental protection. Present legal regulations do not take the following into account3: • Newly synthesized compounds • Unidentified pollutants, due to the imperfection of analytical procedures and of monitoring and measuring instruments The impact of pollutants (mostly from anthropogenic sources) on ecosystems is increasing rapidly. Unfortunately, knowledge about their harmful influence on living organisms is accumulating at a considerably slower pace. At present, List I in Council Directive 76/464/EEC,4 which includes especially

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dangerous pollutants, defined as permanent, toxic, and subject to bioaccumulation, contains 33 priority substances. This list is open; with time and increasing knowledge, new and dangerous compounds, specified by the European Committee, the Council, and member states, are added to it. The requirements concerning the discharge of pollutants specified in List I and the standards of environmental water quality with respect to admissible levels of these substances have been defined at EU level. Where pollution poses a lesser threat but nonetheless restricts or hinders the use of water resources to a significant extent (List II), suitable standards of quality are established at member state level, although they have been introduced for only 25 out of 139 substances. The inconveniences associated with analyzing a complex mixture of pollutants can be avoided by determining the total parameters in a given compartment of the environment. Chemical oxygen demand (COD) and biological oxygen demand (BOD) or total carbon concentration (TC) and total organic carbon (TOC), which measure the total organic matter or the entire content of a given element in the pollutants present in an investigated sample, can be successfully applied in environmental analytics.5,6 Unfortunately, however, the information obtained in this manner is still difficult to convert into knowledge about the toxicity of the environmental compartment in question vis-à-vis its living organisms.7 The diverse bioavailability of the forms in which chemical compounds can occur in the environment makes it virtually impossible to make a reliable risk assessment of potential ecotoxicological effects based on total chemical parameters.8 Bearing in mind the aforementioned problems, one can see that analysis of environmental samples based on the determination of every chemical compound and/or the selection of total parameters may supply only part of the knowledge necessary for assessing the toxic impact of chemicals on living organisms. At present, chemical monitoring is only to a limited extent capable of identifying and determining the quantity of compounds with a possible toxic action. Moreover, the complex interactions taking place between pollutants as well as their different bioavailabilities significantly restrict the ability of such systems to assess the quality of environmental compartments. These limitations of the current system of assessing aquatic environment quality indicate that further research and newer, more reliable tools are needed. Such tools introduced into analytical practice would enable fresh information to be obtained. This information would then complement the data obtained from chemical monitoring and would enable the real risk from the presence of a mixture of diverse pollutants in the environment to be adequately assessed.

9.3 IMPORTANCE OF TOXICITY TESTS Ecotoxicity studies have become increasingly important in pollution assessment; an effective tool and valuable complement to the information obtained from chemical monitoring, they are being implemented more and more frequently. However, until quite recently, toxicity tests served exclusively to determine and compare the toxicity of individual chemical substances, for example, during research conducted in order to authorize the sale of a specific pesticide. In this instance, results in the form of estimated toxicity coefficients are used for the registration, licensing, and enactment of legal regulations for chemical substances. On the basis of toxicity tests, one can also rate the influence of an environmental sample (waters, sediments, or soils), which is a mixture of many chemical substances, on the health status of living organisms. At present, it is usual to assess the effective concentration EC50 in research on environmental samples, although this value is still often identified with the toxic influence of a single chemical compound. Therefore, toxicity tests, or in other words bioassays, can supply information on the total load of an investigated sample in a diverse (in terms of type and quantity) mixture of pollutants, which allows for the possibility of their interactions.8–12 Bioassays are based on the use of particularly sensitive species (bioindicators), which are characterized by their quick reaction to changes in their environment. This results from their relatively low ability to maintain a stable state of equilibrium, that is, from their narrow range of tolerance to specific toxic factors. Such organisms show a special ability to accumulate pollutants.13 Hence, they can work as so-called Biological Early Warning

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Systems (BEWS), delivering the first signals about toxicity in an environmental compartment and simultaneously indicating the need for further, more detailed, analyses using classical methods.14–17 A bioassay may therefore be understood as an analytical method based on the observation of a response at a given level (or levels) of biological organization, resulting from homeostasis disorders induced by changes occurring in a given compartment of the environment (i.e., the occurrence of pollution).18,19 The aim of a bioassay is to prove the presence of toxic substances in the environment and/or demonstrate their harmfulness through the quantitative assessment of a given substance’s impact on living organisms (based on a comparison with a control sample). Measurement of toxicity is thus an example of relative measurement, so common in classical chemical analysis. Bioassays used in analytical practice can be classified according to the type of bioindicators used in a given toxicity test. The organisms most frequently used are bacteria, plants, and animals; detailed information on their application in bioassays to assess environmental pollution is given in a review study.20 In this chapter, we present tables for the use of selected bioindicators in toxicity tests. Basic information about the degree of pollution in a given environmental element is delivered by bioassays done using a single plant or animal species (single species tests) representing a specific trophic state. The tests are conducted according to standardized procedures and under controlled laboratory conditions that are optimal for the tested organism.21–26 Obviously, there is no ideal bioindicator. The selection of a suitable organism for toxicity testing depends on the type of information required, the state, physical and chemical properties of the analyzed sample (its origin), the type of investigated substances or mixture of chemical substances, and the sensitivity of the examined species. Each bioindicator species displays a different sensitivity to different groups of pollutants. This limitation should be considered during the planning and interpretation of bioindicator-based findings on the degree of environmental pollution. A bioassay where only one bioindicator species is used to determine the toxicity reflects only the sensitivity of the tested species. Such a procedure carries the risk of underestimating the toxicity of investigated substances with regard to an entire ecosystem. It is important that toxicity tests be conducted simultaneously with several bioindicators, that is, with a battery of bioassays characterized by different sensitivities and representing different trophic levels.19 Such an approach is often applied in research on environmental samples, which are usually complex mixtures of compounds with unknown physicochemical properties. Single species tests and tests using bioassay batteries are called lower-tier tests.19 But in order to carry out a more stringent examination of the complex interactions between potentially toxic chemical compounds and organisms inhabiting specific ecosystems, experiments are sometimes carried out in microcosms and mesocosms; the literature describes these as higher-tier tests.19 An important requirement for toxicity tests is their reproducibility and repeatability. In conformation with the principles of good laboratory practice (GLP),27 it is recommended that they be performed according to standard procedures and guidelines prepared by world standardization organizations such as the OECD, ISO, or CEN. Table 9.1 presents a list of selected ISO standards and OECD guidelines with regard to the modality of toxicity tests. Many European states have already taken note of the benefits of ecotests; this is reflected in national regulations. Also, the European Commission, in the provisions of the WFD, requires EU member states to have achieved good ecological status of surface waters and groundwaters by 2015, and suggests the use of ecotests as one way of reaching this objective.1 Article 16 of the WFD, which deals with protection strategies against water pollution, stipulates that the order in which activities are undertaken with regard to priority pollutants should be based on the degree of the related threat to the aquatic environment or, through the aquatic environment, to human. Such an assessment can be conducted using a method introduced in Council Regulation 793/93 (on the evaluation and control of the risks of existing substances).28 This assessment refers exclusively to toxicity in aquatic and human environments (exposure through the mediation of water). Additionally, Annex V in the WFD contains recommendations concerning the establishment of environmental

194

Analytical Measurements in Aquatic Environments

TABLE 9.1 Standards (ISO) and Guidelines (OECD) Determining the Manner of Performing Toxicity Tests Using Selected Bioindicators29–32 Number of the Standard/ Research Method–—Assay Guidelines 1 ISO 10712:1995 PN-EN ISO 10712:2001 ISO 11348-1:1998 PN-EN ISO 11348-1:2002

Bioindicator

Type/Application of the Assay

2

3

Bacteria (Pseudomonas putida) Marine luminescent bacteria (V. fischeri)

ISO 11348-2:1998 PN-EN ISO 11348-2:2002

Growth inhibition (testing the inhibition of cell proliferation) Bioluminescence inhibition of bacteria in water samples (method using freshly prepared bacteria) Bioluminescence inhibition of bacteria in water samples (method using dried bacteria)

ISO 11348-3:1998 PN-EN ISO 11348-3:2002

Bioluminescence inhibition of bacteria in water samples (method using lyophilized bacteria) ISO 15522:1999 ISO 8692:2004 PN-EN 8692:2005 OECD 201 (modification of guidelines, passed in 1984)

Algae–—chlorophytes (Scenedesmus subspicatus, Selenastrum capricornutum, Chlorella vulgaris)

Growth inhibition of microorganisms in activated sludge Growth inhibition of freshwater algae

ISO 10253:2006 PN-EN ISO 10253:2002

Algae—diatoms (Skelotonema costatum, Phaeodactylum tricornutum)

Growth inhibition of marine algae

OECD 221(new guidelines, 2000)

Duckweed (Lemna minor) Duckweed (Lemna gibba) Land plants

Growth inhibition

OECD 208 (original guidelines, passed in 1984)

Influence on growth

OECD 208A (project of guideline modifications 2000)

Germination and seedling growth

OECD 208B (project of guideline modifications 2000)

Vegetative abilities

OECD 202 (guideline modifications, passed in 1984)

Freshwater crustacean—Daphnia (Daphnia magna)

Mobility inhibition

Marine crustaceans (Acartia tonsa, Tisbe battagliai, Nitocra spinipes)

Acute toxicity

Chironomidae (Chironomus tentans, Chironomus riparius)

Sediment toxicity

Influence on reproduction

ISO 6341:1996 PN-EN ISO 6341:2002 OECD 211 (original guidelines, passed in 1998) ISO 10706:2000 ISO 14669:1999 OECD 218 (original guidelines, passed in 2000) OECD 219 (original guidelines, passed in 2000)

Water toxicity

continued

195

Application of Biotests

TABLE 9.1

(continued)

Number of the Standard/ Research Method–—Assay Guidelines 1 OECD 207 (original guidelines, passed in 1984) ISO 11268-1:1993 PN-ISO 11268-1:1997 ISO 11268-2:1998 PN-ISO 11268-2:2001 OECD 220 (project of guideline modifications 2000) OECD 203 (guidelines passed in 1992)

Bioindicator

Type/Application of the Assay

2

3

Redworm (Eisenia fetida)

Acute toxicity using artificial soil substrate Influence on reproduction

Potworm (Enchytraeus sp.)

Influence on reproduction

Fish Zebra fish (Brachydanio rerio)

Acute toxicity

ISO 7346-1:1996 PN-EN ISO 7346-1:2002

Acute toxicity (static method)

ISO 7346-2:1996 PN-EN ISO 7346-2:2002

Acute toxicity (semistatic method)

ISO 7346-3:1996 PN-EN ISO 7346-3:2002

Acute toxicity (flow-through method)

OECD 212 (original guidelines 1998) OECD 210 (original guidelines 1992)

Fish Zebra fish (Brachydanio rerio), Rainbow trout (Oncorhynchus mykiss), Fathead minnow (Pimephales promelas)

Toxicity in embryonic stage (shortterm test) Toxicity in early life (fry)

OECD 204 (original guidelines 1992)

Zebra fish (Danio rerio)

Influence on growth (long-term test)

ISO 10229:1994

Rainbow trout (Oncorhynchus mykiss)

quality standards with regard to priority pollutants. If possible, countries should obtain information on the acute and chronic toxicities of these pollutants, both for the “basic set” of species for a given type of water,1 including • Algae and/or macrophytes • Daphnia or organisms representative of saline waters • Fish and also other aquatic species for which such data are available.

9.3.1

TOXKIT TESTS

The tests most frequently used in analytical practice in many countries are conventional toxicity tests, often recommended by national and international standard organizations to assess the toxicity of • Freshwaters using, inter alia, algae (Chlorella vulgaris), daphnia (Daphnia magna Straus), rainbow trout (Oncorhynchus mykiss), zebra fish (Brachydanio rerio Hamilton–Buchanan), guppies (Lebistes reticulatus Peters), and Gammarus varsoviensis (Jaz·dz·.)

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Analytical Measurements in Aquatic Environments

• Saline waters using algae (Skeletonema costatum and Phaeodactylum tricornutum), shrimps (Crangon crangon), Pacific Ocean oyster larvae (Crassostrea gigas), young turbots (Rhombus maximus), and flatfish (Pleuronectes platessa) • Soils using redworm (Eisenia fetida) Despite the increasing popularity of such tests in laboratories worldwide, their deficiencies and limitations should be borne in mind. They demand continuous cultivation of test organisms, which considerably increases research costs. At the same time, because of changes occurring in the populations of bioindicator organisms, considerable differences in sensitivity can arise between test organisms originating from different laboratories.19 Moreover, the results of a conventional test are obtained over a period ranging from 24 h to several days, which means that this type of test is practically useless for a pollution event that requires immediate action. The need to perform environmental studies on an increasing scale in order to obtain the most comprehensive information on the state of the environment and its processes has led to an increase in the importance and range of rapid miniaturized bioassays, variously known as microbioassays, alternative tests, or second-generation assays.33 The bioassays utilize unicellular or small multicellular organisms that exhibit a specific response on contact with a liquid sample. Bioluminescent bacteria are exceptionally sensitive, and even trace quantities of toxins in water reduce the amount of light they emit. In 1979, this phenomenon was used to assess the degree of pollution in water samples, the intensity of the bioluminescent light of these bacteria being measured.34 A year later, the American company AZUR Environmental (formerly Microbics Corporation) manufactured the first specialist equipment—Microtox®—for carrying out analyses of environmental samples. Nowadays, Microtox is the most popular bioassay available that uses bioluminescent bacteria as its active element. Analysts find it a useful tool for assessing pollution in different compartments of the environment, possessing as it does both the advantages of bioindicator techniques and the precision of classic instrumental analysis. Here are some examples of its application: Monitoring of surface water quality35–38 Monitoring of groundwater39,40 Determination of soil and sediment toxicity39–49 Investigation of leachates from landfill sites39,50–52 Initial determination of the toxicity of sewage delivered to a sewage treatment plant39,49,53–59 • Monitoring the stages of the treatment of municipal, industrial, and pesticide sewage7,39,49,54,60–64 • Monitoring of treated sewage at each stage of purification, and of water before and after water dumping39,45 • Monitoring the treatment stages of water for drinking purposes39

• • • • •

During the 30-year period of Microtox usage, 1500 potentially toxic substances have been tested and an immense number of environmental samples examined; the results have spawned several hundred research papers.65 The sensitivity of bacteria to the presence of simple organic substances is similar to that displayed by daphnia and fish. However, there was greater differentiation with respect to the toxicity of larger molecules (pesticides and pharmaceuticals) and complex effluents, for example, from the pharmaceutical and chemical industries. The German DIN standards and international ISO standards recommend the use of bacteria that have been freeze-dried or have originated from continuous cultivation conducted in a laboratory. Vibrio fischeri bacteria are available on the market in freeze-dried form. After hydration, their cell walls are slightly

197

Application of Biotests

TABLE 9.2 Types of Information Obtained Based on Toxicity Assays Conducted for Bioluminescent V. fischeri Bacteria66 Type of Assay

Type of Obtained Information

Screening test

Results of the assay answer the question whether a sample is toxic or not. To this end, an undiluted sample is subjected to analysis. If a decrease in the intensity of bacterial luminescence is smaller than the established threshold value, then the sample need not be subjected to further research. Results of the assay answer the question about the toxicity of a sample. The sample for which a decrease in the intensity of bacterial luminescence exceeds an established threshold value is subjected to detailed analysis in a series of dilutions and determination of toxicity index, e.g., EC50.

Basic test

damaged, which enables easier absorption of toxic substances. Their sensitivity to organic compounds is several times greater than bacteria derived from a fresh culture.67 Thanks to the use of standard bacterium strains (NRRLB-11177), the quality of which is guaranteed by the manufacturer; the repeatability of results is very high. Research on toxicity using bioluminescent bacteria can be conducted in two ways. Table 9.2 lists the types of information obtainable, depending on the form of the assay. The Microtox system requires neither specialist training nor experience in work with bioindicators: the results of an assay are read automatically. As opposed to other bioassays, staffs are not required to have received a specifically biological education. The results of toxicity determinations for a whole series of samples examined at the same time are obtained within 30 min. This enables quick and effective action to be taken, which is especially important in monitoring drinking water, in assessing the efficiency of sewage treatments, and in testing the toxicity of surface waters above and below sewage outfalls. The Microtox test can be used in field studies and in mobile laboratories.7,8,54 This is especially important in unexpected and rapidly developing environmental threats, when continuous inspection of pollution levels is necessary.68 Since the test is instantly applicable, and because the results are obtained within an hour of the sample being delivered to the laboratory, this type of assay has become very popular worldwide. But despite the aforementioned advantages, this system is not perfect. The most important shortcomings are • Tests can be carried out only on samples that are colorless (although color correction is possible), clear, and of low viscosity. • The formation of complex compounds with chloride ions in the case of samples polluted by heavy metals can lead to erroneous results (a solution of sodium chloride is added to the sample to obtain the appropriate conditions for bacteria).69 • The need for an additional device to control pH in the samples under examination (the optimum pH range is 6–8). • The required presence of sodium ions in the analyzed sample, which regulates the stages of bacterial bioluminescence.69 Assays based on the application of bioluminescent bacteria are attracting increasing interest; in 1991, their use was regulated by the standard DIN 38412 (part 34). Although this standard was developed with regard to the control of harmful substances occurring in sewage, it can be applied to any type of water—from drinking water to water passing through a landfill.

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Analytical Measurements in Aquatic Environments

The assays are available worldwide in the form of ready-made kits, which enable the toxicity in samples to be estimated in a short time. Work on the idea and development of a methodology for microbioassays (commonly known as Toxkits) using microorganisms not requiring continuous cultivation was pioneered by a team of scientists led by Professor Guido Persoone of Ghent University, Belgium.70–72 Toxkits contain microbioassays equipped with all the accessories (including test organisms) necessary for easy, quick, sensitive, and repeatable toxicity assays.73 Bioindicator organisms (from standard cultures) are provided to a laboratory in cryptobiotic form, that is, in a state of physiological rest (dormancy), for example: • Rotifer cysts • Crustacean eggs • Algae—in the form of cells immobilized in a suitable medium and prevented from proliferating by a special solution Organisms in such forms can be kept refrigerated for several months; when necessary, they are quickly prepared (“on demand”) for an assay. Prior to an assay, the cysts or eggs are placed in water. Under the influence of strong light, these forms begin to grow and after 18–96 h (depending on the organism) a batch of young organisms is generated, ready to be used as biological components for a suitable assay.74,75 The test organisms most often used in toxicity microbioassays are Daphnia magna, Daphni pulex, and Ceriodaphnia dubia.76 These crustaceans, like rotifers and protozoans, are typical organisms whose natural environments are aquatic ecosystems. Their eggs, included in the kit, are protected by chitinous capsules (Lat. ephippium) and can be kept for a long time without any loss of properties. Microorganisms lie at the lowest level of the trophic pyramid, which is why any adverse changes occurring in them may directly or indirectly affect organisms at higher trophic levels, and consequently the state of the entire ecosystem. Because of their large surface area and the immediate contact of a cellular membrane with the investigated medium, microorganisms are more sensitive to toxic substances than invertebrates or fish.33 Toxicity is typically a function of exposure duration, which is why long-term assays have special importance in ecotoxicology. However, using long-lived species is troublesome. Microorganisms characterized by the short life span of a single generation provide a convenient means of determining the effect of chronic exposure to a toxic substance. The growing interest in this approach to environmental pollution studies is also due to other factors, such as73 • • • • • •

The elimination of continuous cultivation The low costs of conducting a single sample analysis The possibility of testing several samples simultaneously The short response duration The small sample volume of a sample The small space occupied in the laboratory, and also the possibility of conducting research in the field (in situ)

Because of the numerous benefits of Toxkit assays, they can be used for sample testing even by small analytical laboratories and local monitoring stations for routine toxicity assessments of environmental samples as well as in emergencies. The use of standard organisms means that assays can be standardized and that repeatable results can be obtained in different laboratories. Another, not unimportant aspect is that conducting toxicity assays on microorganisms does not require the consent of an ethical committee.77 Table 9.3 provides information on microbioassays commercially available in kit form (Toxkit).73

MARINE ALGALTOXKIT ROTOXKIT MTM ARTOXKIT MTM

TM

Algae (diatoms) Rotifers Crustaceans (fairy shrimp)

Plants (monocotyledons and dicotyledons)

PHYTOTOXKITTM

Phaeodactylum tricornutum Brachionus plicatilis Artemia franciscana (previously Artemia salina)

72 h 24–48 h 24–48 h

72 h

24 h 6 days

24–48 h 24–48 h 24 h 24 h 30–60 min 24 h 48 h

72 h

4

Test Duration

Estuarine and Marine Environment

1. Sorghum saccharatum 2. Lepidium sativum 3. Sinapis alba

Tetrahymena thermophila Heterocypris incongruens

Rotifers

Protozoans (ciliates) Crustaceans (ostracods)

Brachionus calyciflorus

Crustaceans (daphniae) Crustaceans (daphniae) Crustaceans (daphniae) Crustaceans (fairy shrimp)

DAPHTOXKIT FTM magna DAPHTOXKIT FTM pulex CERIODAPHTOXKIT FTM THAMNOTOXKIT FTM RAPIDTOXKITTM ROTOXKIT FTM ROTOXKIT FTM short-chronic

PROTOXKIT FTM OSTRACODTOXKITFTM

Selenastrum capricornutum (Raphidocelis subcapitata or Pseudokirchneriella subcapitata) Daphnia magna Daphnia pulex Ceriodaphnia dubia Thamnocephalus platyurus

Freshwater Environment

3

Test Species

Algae (chlorophytes)

2

Taxon

ALGALTOXKIT FTM

1

Toxkit

TABLE 9.3 List of Commercially Available Microbioassays

Chronic toxicity (growth inhibition) Acute toxicity Acute toxicity

Acute toxicity Acute toxicity Acute toxicity Acute toxicity Acute toxicity for larvae Acute toxicity Short-term chronic toxicity (reproduction) Chronic toxicity (growth inhibition) Chronic toxicity (lethality/growth inhibition) Chronic toxicity (inhibition of germination and root growth)

Chronic toxicity (growth inhibition)

5

Type of Test

ISO ASTM —

—

OECD —

OECD, ISO OECD US EPA — — ASTM AFNOR

OECD, ISO

6

Recommended by

Application of Biotests 199

200

Analytical Measurements in Aquatic Environments

9.4 INTEGRATED SYSTEM OF WATER POLLUTION ASSESSMENT The stipulations of the WFD, concerning the obligation to carry out monitoring, provide legal regulations for 172 priority pollutants.1,4 However, it has been estimated that there may be some 100,000 substances (in different and varying concentrations) in the aquatic environment. This means that the vast majority (>99%) of pollutants are not covered by chemical monitoring.78 The results obtained from toxicity assays are thus a valuable complement to the information derived from physicochemical and chemical studies. This simultaneous use of monitoring and ecotoxicity assays to assess the quality of the environment is called an integrated approach or integrated tool; recent years have seen a rise in its popularity among analysts. This interest is engendered by the significant information that can be obtained with this approach: information relating to the complex interactions occurring between pollutants and the different bioavailability of the forms in which these pollutants can occur. The main sources of environmental water pollution are industrial effluents, municipal sewage, and run-off waters. Somewhat less significant is the influence of landfill site effluents and sewage sludge. Because of the pollutant load they contain, all these “waters” must comply with rigid requirements before entering the environment so as to prevent deterioration in its quality. Information on the potential risks posed by the release of these pollutants into aquatic ecosystems is a good basis for determining • The discharge of effluents and landfill waters into the environment. • The effectiveness of treating effluents and landfill waters. • The manner of storage or use of sludge. The United States is the leader as regards the integrated assessment of the quality of effluents introduced into aquatic environments. In 1984, the United States Environmental Protection Agency (US EPA) introduced the notion of Whole Effluent Toxicity (WET). WET assays may involve the following samples:79 • • • •

Municipal run-off waters (precipitation) Municipal (household) sewage Mine effluents (from the drainage of mines) Run-off waters from fields (containing pesticides and loaded with nutrients as a result of the application of fertilizers) • All types of industrial effluents • Landfill leachates (water drained from the bottom of a landfill) as well as other mixtures with complex compositions that could enter the environment but whose exact composition and toxicity is unknown. Depending on the country, the approaches to ecoassay use in assessing effluent quality vary and are described by different names.80 In Australia and New Zealand, and also in Great Britain, the notion of direct toxicity assessment (DTA) began to be used at the beginning of the 1990s in relation to the immediate assessment of toxicity, both in effluent samples and in samples of waters into which the effluents are discharged. In European countries and in the United States WET is used, but this additionally includes tests for the bioaccumulation, biodegradation, and persistence of pollutants in the environment. The notion of Whole Effluent Assessment (WEA) has become especially common in Europe since 2000 following the Oslo-Paris Commission agreement (OSPAR).81 In a nutshell, WEA combines tests of acute and chronic toxicity, bioaccumulation, mutagenicity, and persistence.82 Sometimes, it also includes measurements of total parameters, such as BOD, COD, or TOC.80 In the future this type of assessment may also include the concentrations of endocrine

Application of Biotests

201

disruptors, whose presence can lead to disorders in hormonal and immunological systems.82 In Germany, the term ICE is used (Integrated Control of Effluents) and in the Netherlands WEER (Whole Effluent Environmental Risk) is used. In different compartments of the environment, sediments accumulate mainly heavy metals and persistent organic pollutants (POPs), which reach aquatic ecosystems from different sources. Metal ions do not remain dissolved in water for long: they are liable to be precipitated as a result of oxygenation, the formation of different compounds (carbonates and sulfates), or sorption on mineral surfaces and the organic fraction of sediments.83 The bioavailability of pollutants adsorbed on the surface of sediments is very important in toxicity assessment. Chemical analysis enables the quantitative determination of toxic substances in sediment samples or those present in aqueous phases, for example, in pore water. However, the solubility, mobility and, in later stages, the availability to benthic organisms of pollutants such as metals and organic pollutants are all also influenced by a number of other parameters, for example, the pH of the environment, TOC concentration, or the granulometric distribution of sediments.42 The pH value is often considered to be the main factor influencing the mobility of metal ions.52 As numerous reports have shown, the total concentration of metals in a sample cannot be treated as a measure of its toxicity. Only the form in which a given metal appears, that is, dissolved (ionic), or as a compound with organic or inorganic substances, determines the bioavailability of the metal and its toxicity toward living organisms. This is why it is so significant to combine the two types of assay: toxicity assays and chemical analysis. Table 9.4 presents a list of studies on the pollution levels of effluents, landfill leachates, sludge, and sediments, undertaken using an integrated approach to pollution assessment, that is, the simultaneous use of chemical analysis and bioassays.

9.5 LEGAL REGULATIONS APPLYING TO THE USE OF BIOASSAYS IN ENVIRONMENTAL MONITORING The integrated approach to environmental pollution assessment and the practical use of such testing in environmental management is developing intensively in Western Europe (Germany, Belgium, the Netherlands, Italy, Sweden, and Norway), Canada, the United States, Australia, and New Zealand, and also in some postcommunist countries (Lithuania, Estonia, and Slovakia).96 Table 9.5 presents information on legal regulations (on national and regional levels), valid in the countries of Northern America and Europe, applying to the measurement of toxicity in environmental samples.

9.6 ECOTOXICOLOGICAL CLASSIFICATION OF ENVIRONMENTAL SAMPLES The results of analytical determinations (including ecotoxicological assays) obtained during monitoring measurements are usually converted into information intelligible to nonspecialists in the field of analytics. Classification systems are one way of presenting monitoring databases in a nontechnical fashion. The results of toxicity assays enable the ecotoxicological quality of environmental samples to be assessed on the basis of the value (expressed as a percentage) of the observed effect of toxic activity, for example, bioluminescence inhibition, algal growth inhibition, and lethalities of crustaceans, as well as estimated toxicity indices such as L(E)C20, L(E)C50, or toxicity unit (TU). The principles of ecotoxicological quality classification based on the TU index are included in the 2002 recommendations of the Helsinki Commission (HELCOM). The classification applies to samples of treated effluents discharged to waters from industrial plants manufacturing chemicals,98 textiles,99 and pesticides.100 HELCOM recommends testing the acute toxicity of effluent samples using two of the four suggested indicator organisms (Table 9.6).

Sludge (municipal and industrial)

Sludge (municipal and industrial)

Municipal and industrial effluents

Industrial effluents

1

Matrix

PCB, PAH TOC Heavy metals: As, Cd, Cr, Cu, Pb, Mn, Zn PAH

Organic compounds: chloro- and nitrophenols, nonionic surfactants, linear alkylated benzene sulfonates, benzene and naphthalene sulfonates, estradiol, ethinyl estradiol BZT7, COD NNH4, Ntot, Ptot General suspensions Heavy metals: Cd, Cr, Cu, Mn, Ni, Pb, Zn

2

Spectrum of Compounds and Parameters Tested for

Significant correlations were found between EC20 values and the concentrations of almost all PAH compounds, PCB-118, Pb, and Zn

There were significant correlations between the total content of PAH compounds and the indices assessed—–TII50 (15 min) and TII50 (30 min) The high phenanthrene content had a significant influence on the toxicity of the samples

V. fischeri (ToxAlert® 100)

Sludge

Effluents There were certain correlations between the results of the chemical analyses and bioassays; to a large extent, however, the composition of the samples remained unknown Distinct correlations were found between the inhibition of bioluminescence and compound content, but only in the case of nonylphenol, nonylphenol carboxylate, nonylphenol ethoxylate, and chlorophenols Significant correlations were found between the indices of chemical pollution and toxicity (chemical pollutants explain about 70% of the toxicity variability) Conformity between chemical parameters and toxicity indices was greatest when the tests included information obtained from all the tests in a battery (and not just the toxicity indices of the most sensitive assay)

4

Notes

V. fischeri (LUMIStox®)

Selenastrum capricornutum (Algaltoxkit F TM) Nitellopsis obtusa (Charatox) Daphnia magna (Daphtoxkit F TM magna) Thamnocephalus platyurus (Thamnotoxkit F TM) Tetrahymena thermophila (Protoxkit FTM) V. fischeri (Microtox®)

V. fischeri (ToxAlert® 10, ToxAlert® 100)

3

Bioassays

86

8

85

84

5

References

TABLE 9.4 Examples of Studies on the Pollution Caused by Effluents, Landfill Leachates, Sludge, and Sediments Based on the Simultaneous Use of Chemical Analytics and Toxicity Assays

202 Analytical Measurements in Aquatic Environments

The observed toxicity to bioluminescent bacteria was strictly correlated with the content of elemental sulfur and sulfides Owing to the low levels of metals in the bioavailable fraction, there was no correlation between their content and the observed toxic effect No distinct linear correlation was found between toxicity and the presence of the organic compounds investigated

V. fischeri (Microtox® Basic Solid-phase Test, Microtox® Acute Toxicity Basic Test)

V. fischeri Daphnia magna

Heavy metals: Hg, Pb, Cu, Ni, Zn, Mn, Fe, Cd TOC Humus compound content Sulfur and nitrogen content PAH TOC

Freshwater sediments

No correlation was observed between the toxicity and the TOC or concentration of individual heavy metals (taking account of their concentration in a bioavailable fraction). Therefore, there may have been interactions between individual components of the sediments and other pollutants

Heavy metals: Cd, Pb, Cu, Cr, Zn, Mn, Ni, Fe TOC

Marine sediments

Sediments V. fischeri (LUMIStox®)

Phenols Sulfates

V. fischeri (Biotox®, Microtox®) Daphnia pulex (Daphtoxkit F TM pulex) Brachionus calyciflorus (Rotoxkit F TM)

Selenastrum capricornutum (conventional assay)

pH COD NNH4, Ntot, Ptot, sulfates General suspensions, dissolved substances Heavy metals: Cd, Cr, Cu, Mn, Ni, Pb, Zn, Fe

The observed toxicity to both bacteria and algae was due to the presence of nonvolatile organic compounds, mainly naphthalene and 4-chloro-m-cresol (volatiles were lost during sample preparation) Assays using bacteria were generally more sensitive than those using algae. In certain cases, however, the reverse situation prevailed; a battery of bioassays was then applied The worst polluted sample (according to the number of compounds identified) was also the most toxic. The concentration levels at which pollutants occurred in the samples had no direct influence on their toxicity The concentration of metal ions in a landfill leachate sample depended on the pH and the content of organic compounds; the latter may have bound metal ions in complexes, thus decreasing their bioavailability (a high organic matter content causes a reduction in toxicity) The total concentration of metals in a sample provides no reliable information on its toxicity Bioassays provide information on the chemical speciation of metals and their bioavailability Bioassays based on bacteria proved to be the most sensitive, while those based on rotifers were the least sensitive. At the same time, bacterial bioassays were deemed the most suitable for screening tests The results of the bacterial bioassays indicated that the toxicity of the samples was caused mainly (75%) by phenols (p-cresol, 3,4-dimethylphenol, and phenol), and to a lesser degree by sulfates (about 25%)

Landfill Leachates V. fischeri (Biotox®); Selenastrum capricornutum (conventional assay); Salmonella typhimurium (UmuC)

Organic compounds: BTEX; propyl benzene derivatives, bicyclic compounds, naphthalenes, chlorinated aliphatic compounds, phenols, pesticides, and phthalates

Leachates from the oil-shale industry and from spent shale dumps

Municipal landfill leachates

continued

90

89

88

87

52

51

Application of Biotests 203

Extract samples were divided into fractions for a toxicity assessment and the identification of toxic compounds The high toxicity of the acetone extract samples obtained from the sediments to V. fischeri was due to the presence of elemental sulfur The toxicity due to the total toxicity of individual fractions was significantly greater than that calculated for the complete extract The toxicity due to the total toxicity of individual subfractions significantly exceeded that calculated on the basis of the examination of an individual fraction

V. fischeri (LUMIStox®) Lemna minor

V. fischeri (LUMIStox®) Daphnia magna (conventional assay) Scenedesmus vacuolatus (conventional assay)

The toxicity was probably associated with the presence of aliphatic compounds and elemental sulfur The difficulty in finding a correlation between the results of chemical analyses and ecotoxicological assays may have been due to antagonistic and synergic effects

Daphnia magna Selenastrum capricornutum Pimephales promelas Hyaella azteca

Heavy metals PAH PCB

HCH DDT PAH Tributyltin Saturated, unsaturated, and aliphatic carbohydrates Biphenyls Elemental sulfur Aromatic esters

A connection was found between the bioavailability of metals and their toxicity Chemical analyses revealed a high content of organic compounds (mainly PAHs), which were probably responsible for the observed toxic effect

V. fischeri (Microtox® Solid-Phase Test) Corophium volutator Acartia tonsa Skeletonema costatum

Heavy metals PAH PCB

Fluvial sediments

No elemental sulfur S8 was detected in groundwater samples The bioavailable fraction (responsible for the inhibition of bacterial bioluminescence) constituted only 3–8% of the total content of elemental sulfur in the sample No distinct correlation was found between toxicity and the presence of the compounds identified in the samples

V. fischeri (Microtox® Basic Solid-Phase Test)

Elemental sulfur

PAH TOC

An immediate assay of sediment samples enabled the toxicity due to the presence of inorganic pollutants (metals and sulfates) to be assessed. The assay of organic extracts obtained from the samples enabled the toxicity due to the PAH or PCB content to be determined

4

Notes

V. fischeri (Microtox® Basic Solid-phase Test, Microtox® Basic Test–—assay with organic extracts)

3

Bioassays

PCB PAH Heavy metals: Hg, Cu, Ni, Co, Cd, Pb, Zn, Fe, Cr Sulfur

2

Spectrum of compounds and Parameters Tested for

(continued)

Marine sediments

Port sediments

Sediments taken from sewers

1

Matrix

TABLE 9.4

95

94

93

92

91

40

5

References

204 Analytical Measurements in Aquatic Environments

205

Application of Biotests

TABLE 9.5 Legal Regulations (on National and Regional Scales) in Various Countries of North America and Europe Applicable to the Measurement of Toxicity97 Country United States of America

Legal Regulations Studies of toxicity in the aquatic environment are performed to assess potential threats and risks related to the discharge of municipal and industrial effluents to waters. The discharge of industrial effluents is regulated by US EPA in the program of permissions issued by the National Pollutant Discharge Elimination System–—NPDES, which was founded by the Clean Water Act (CWA). The toxicity monitoring, required by the permission, is a program for supervising and maintaining the quality of waters in which toxicity assays are performed at regular intervals (once in 3–4 months) so as to establish whether life in a given aquatic environment is safe from any risk related to pollution discharge. Bioindicators and the methods applied are described in US EPA documents, for example: • US EPA 1991a: Methods for measuring the acute toxicity of effluents to aquatic organisms EPA-600/4-90-027 • US EPA 1991b: Short-term methods for estimating the chronic toxicity of effluents and receiving waters to freshwater organisms EPA-600/4-91/002

Canada

Standard methods for assessing the toxicity of waters and effluents also include chapters on toxicity tests. Similarly, the American Society for Testing and Materials–—(ASTM) has published standard procedures for toxicity determination. Federal law requires the combination of acute lethality and sublethal toxicity tests for effluents from paper mills and metallurgical plants. Discharge of effluents from other industries is regulated by various local administrations Legal regulations are based on the following tests: 1. 2. 3. 4.

United Kingdom

Luminescence inhibition test with bacteria Algal growth inhibition test Test of acute toxicity to Daphnia magna or Ceriodaphnia dubia Test of acute toxicity to fish

A set of methods is being developed for a DTA of effluent toxicity, which is to meet the requirements of SNIFER (Scotland and Northern Ireland Forum for Environmental Research). The set includes the following toxicity tests: – Algal growth inhibition test – Daphnia magna immobilization test – Juvenile fish lethality test

France

Germany

The decree of October 28, 1975, stipulates that the discharge of effluents is subjected to taxation, the level of which depends on the number of “TU,” determined by a test of acute toxicity to Daphnia magna. The tax is collected by “Agences de Bassin” The different Länder in Germany require the following tests in the control of effluents: 1. 2. 3. 4. 5. 6.

Austria

Luminescence inhibition test with bacteria Algal growth inhibition test Acute toxicity test with Daphnia magna Acute toxicity test with fish (soon to be replaced by a test on fish eggs) Genotoxicity test by the Umu assay Toxicity test on higher plants (Lemna)

Toxicity tests of waters are required to assess potential threats connected with the discharge of municipal and industrial effluents to receiving waters. Effluents from water treatment plants and receiving waters are periodically monitored and regulated by the Austrian authorities. continued

206

TABLE 9.5

Analytical Measurements in Aquatic Environments

(continued)

Country

Spain

Legal Regulations Austrian (ÖNORM) and German recommendations (DIN) use the following four standard toxicity tests: – Luminescence inhibition test with bacteria – Acute toxicity test with Daphnia – Acute toxicity test with fish – Algal growth inhibition test In order to determine the threshold of safety for all the toxicity tests for effluents and receiving waters, a G value is used. The G values depend on the type of emission: GL (bacteria), GD (Daphnia) GF (fish), and GA (algae). The G values for industrial effluents, and discharges from paper mills, textile plants, tanneries, chemical plants, and detergent production plants are GF = 2; GL and GD = 4; and GA = 8. Effluents from the pharmaceutical industry and pesticide production plants are limited by the legal requirement of GA = 16. For municipal effluents, only the test on fish is required, and the value GF needs to be smaller than 2. The frequency of toxicity tests is once in five years, but individual regulations may be more restrictive. Toxicity testing is required by the authorities responsible for river basins as a complement to chemical analysis. In their Order No. 10/1993 of October 26, 1993, the regional authorities of Madrid require the toxicity of effluents to be tested using the following assays: – – – – – –

Portugal

Luminescence inhibition test with bacteria Algae growth inhibition test Acute toxicity test with Daphnia magna Respiration inhibition test on sludges Acute toxicity test with rotifers Acute toxicity test with Thamnocephalus

Three microbioassays (Toxkits) were accredited by the Portuguese Institute for Standardization in 2001: – Daphtoxkit F magna microbiotest (acute toxicity tests with Daphnia magna) – The Thamnotoxkit F microbiotest (acute toxicity tests with Thamnocephalus platyurus) – The Artoxkit M microbiotest (acute toxicity tests with Artemia salina/franciscana)

Norway Sweden

Italy

The assays are to be included in the national law as official ecotoxicological parameters. The State Pollution Control Authority requires ecotoxicological characterization of industrial effluents in combination with the renewal of permissions for the discharge of effluents. Although Swedish legislation does not require determination of the toxicity of effluents, it nevertheless indicates that those who might affect the natural environment have to prove that their actions do not adversely affecting it. As a result, many industrial effluents are in practice examined with regard to their toxicity to selected bioindicator organisms. Since 1999 toxicity assays for effluents are required by law (order D.L. 152/99). The following tests are recommended: – – – –

Denmark

Acute toxicity test on Daphnia magna or Ceriodaphnia dubia Algal growth inhibition test on algae Selenastrum capricornutum Luminescence inhibition test on bacteria Acute toxicity test on Artemia salina (for saline discharges)

Industrial effluents discharged directly to receiving waters have to be tested for toxicity within the framework of discharge consents. The applied toxicity assays conform with international recommendations, that is: – Algal growth inhibition test – Acute toxicity test with Daphnia – Acute toxicity test with fish continued

207

Application of Biotests

TABLE 9.5

(continued)

Country Belgium

Legal Regulations Flanders The Flemish Environmental Agency may order industrial plants to perform toxicity assays, so plants obtain permission to discharge their effluents. At present, many plants are asked, at regular intervals (a few times a year) to perform toxicological tests on their effluents. The effluents are initially subjected to the following assays: – – – –

Luminescence inhibition test with bacteria Growth inhibition test with algae Acute toxicity test with Daphnia magna Acute toxicity test with fish

Subsequent effluent analyses are performed on those organisms that have proved to be the most sensitive in the battery of tests.

Greece

Czech Republic Poland

Wallonia The system is basically similar to the Flemish one, but it is still in preparation. There are no legal regulations on the use of ecotoxicological assays in environmental monitoring, but there are many ongoing research projects which include ecotoxicological assays, mainly concerning effluents. There are no legal regulations on the use of ecotoxicological assays in environmental monitoring. There are no legal regulations on the use of ecotoxicological assays in environmental monitoring.

For example, the use of toxicity assays with V. fischeri bacteria and Daphnia magna crustaceans, for which the TU index is 8, gives a No Observed Effect Concentration (NOEC) of 12.5% (Equation 9.1): 100 . TU = ______ NOEC

(9.1)

Effluents should therefore be of such a quality that at a dilution of 1:7 (12.5%) acute toxicity is not observed in V. fischeri and Daphnia magna. If NOEC < 12.5%, then the ecotoxicological quality of the investigated effluents is poor and they cannot be released to surface waters. In 2003, Professor Persoone et al.101 developed a classification of acute toxicity levels in natural waters and effluents discharged to these waters based on two systems: • A hazard classification system for natural waters • A toxicity classification system for wastes discharged into the aquatic environment

TABLE 9.6 List of Toxicity Tests and Critical Values of the TU Index According to the Recommendations by the HELCOM100 Bioindicator Fish Daphnia crustaceans Algae V. fischeri bacteria

Test Duration (h)

TU Index Value

96 48 72 0.5

2 8 16 8

208

Analytical Measurements in Aquatic Environments

TABLE 9.7 Hazard Classification System for Natural Waters According to Persoone101 Class

PE Value

Hazard

I

<20%

No acute hazard

II

20% £ PE < 50%

Slight acute hazard

III

50% £ PE < 100% 100% in at least one test 100% in all tests

Acute hazard

IV V

High acute hazard Very high acute hazard

Each of which is in turn based on two criteria: • A ranking in five acute hazard classes • A weight score for each hazard class Natural waters are classified according to the percentage effect (PE) obtained with each of the microbiotests. The water is ranked into one of five classes on the basis of the highest toxic response shown by at least one of the tests applied. Table 9.7 shows the classification system for natural waters. The toxicity of effluents discharged into the aquatic environment is also classified using the numerical value of the PE index obtained in a test on an undiluted sample. However, for samples in which PE > 50%, additional assays are conducted in which increasing dilutions of the examined samples are tested. The L(E)C50 values obtained are converted into TU. Depending on the numerical values of the TU index, effluent samples are classified according to the criteria listed in Table 9.8. The advantage of these systems is the possibility of estimating the weight score for each hazard class to indicate the quantitative importance (weight) of the toxicity in that class. The class weight score is calculated according to the following equation: Â all test scores class weight score = _____________ , n

(9.2)

where n is the number of tests performed. The percentage value of the class weight score is calculated in the following way: class score class weight score in % = ________________________ ¥ 100. maximum class weight score

TABLE 9.8 Toxicity Classification System for Effluents Discharged into the Aquatic Environment According to Persoone101 Class

TU Value

Hazard

I

<0.4

No acute hazard

II

0.4 £ TU < 1

Slight acute hazard

III

1 £ TU < 10

Acute hazard

IV

10 £ TU < 100

High acute hazard

V

≥100

Very high acute hazard

(9.3)

209

Application of Biotests

TABLE 9.9 Ecotoxicity of Surface Waters Based on the CF36 Risk for Aqueous Environment

CF Value Corresponding the EC50 Value for Daphnia magna

CF Value Corresponding the EC50 Value with V. fischeri

High

£10

≤40

Medium

£20

≤80

Low

>20

>80

This takes into account the number of tests performed on various bioindicators (the greater the number of tests performed, the more reliable the assessment of a given sample) and the variability in the toxicity estimated using various bioindicators (plants and animals). In their study of surface waters in the Po River basin (Italy), Galassi et al. introduced a classification of ecotoxicological quality based on the concentration factor (CF).36 The pollutants present in a sample were enriched by solid-phase extraction (SPE). This procedure enabled the samples to be differentiated ecotoxicologically in that the presence of only those toxic compounds extractable with a particular solvent were determined. Ecotoxicity was assessed according to the criteria set out in Table 9.9, the most toxic effect being observed with V. fischeri during a 30-min test or Daphnia magna during a 48-h test. The German Federal Institute of Hydrology (Bundesanstalt für Gewässerkunde—BfG) has developed a system of ecotoxicological classification of sediments based on the numerical pT value (potentia toxicologiae).102 This value is the negative binary logarithm of the dilution coefficient of a sample in which no acute toxicity is recorded. In other words, the numerical pT value shows how many times a given sample should be diluted (in a 1:2 ratio) for it to cease being toxic. The pT value determined for the most sensitive bioindicator among all the organisms in the battery of bioassays gives the toxicity class of a given sediment. All the toxicity tests applied, and also all the liquid phases examined—pore water103 as well as aquatic or organic elutriates—are equivalent to the criteria established by Krebs (Table 9.10). For example, if the first pT value for which no toxic effect is observed is equal to 5, then the sediment examined belongs to toxicity class V. The ecotoxicological quality of sediments can also be assessed using the classification developed by the ARGE-Elbe project.104 It allocates sediment samples to one of five ecotoxicological quality classes on the basis of the recorded PE (Table 9.11).

TABLE 9.10 Ecotoxicological Classification of Sediments Based on the pT Value102 Classification of Sediments with Regard to Environmental Management Highest Dilution Level without Effect

Dilution Factor

pT Value

Toxicity Classes

Color Coding

Undiluted Sample

20

0

0

0

1:2 1:4 1:8 1:16 1:32

2−1 2−2 2−3 2−4 2−5

1 2 3 4 5

≤2−6

≥6

I II III IV V VI

I II III IV V VI

≤(1:64)

Three-Level Assessment System Unproblematic

Critical Hazardous

210

Analytical Measurements in Aquatic Environments

TABLE 9.11 Ecotoxicological Classification of Sediments Developed in the ARGE–Elbe Project104,105 Toxicity Class I II III

PE Value

Ecological Status (with Reference to WFD)

Color Coding

£15%

Very good

Blue

>15% PE £ 30%

Good

Green Yellow

>30% PE £ 50%

Moderate

IV

>50% PE £ 70%

Weak

Orange

V

>70%

Bad

Red

In recent years, more complex systems for classifying the toxicity of aquatic environmental samples have been developed, for example: • Potential ecotoxic effects probe (PEEP)106–108 • Potentially affected fraction (PAF)109,110 • Sediment toxicity (SEDTOX)111 Also, a sediment quality system has been developed that combines chemical analyses with biotic indices in the so-called TRIAD (Sediment Quality Triad-integrated assessments of sediment quality based on measures of chemistry, toxicity, and benthos).112

9.7

BIOASSAY APPLICATION IN ENVIRONMENTAL MONITORING: SOME CASE STUDIES

The information contained in the results of an ecotoxicity study has a special significance with respect to chemical analysis. Integrating chemical and ecotoxicological studies offer the same advantages as environment quality estimation and enables • Samples to be screened for further chemical monitoring tests and/or tests for identifying toxic substances • Pollution hot spots to be identified and inventorized • Monitoring stations to be identified where chemical parameters have not been correctly defined • The problems occurring in a given area to be prioritized • The real risks resulting from the bioavailability and mobility of pollutants to be determined

9.7.1

IDENTIFICATION OF TOXIC COMPOUNDS

Detecting and identifying toxic compounds in environmental samples (compounds with unknown structures and properties) require the use of time-consuming, costly methods to isolate them from the matrix, then the application of complex techniques to separate the compounds present in an extract, and finally the determination of their structure (identification). Applying such a procedure to all samples collected from a selected area is very expensive. Samples therefore need to be selected, for example, with the aid of the results of ecotoxicological tests: samples with the determined toxicity may contain toxic compounds. A procedure of this kind was used in the International Odra Project—IOP (1997–2001).113 Screening tests of water samples on V. fischeri bacteria showed that samples taken from two measuring stations (the town of Brzeg Dolny and the confluence of the Mała Panew River with the Odra River, Poland) were toxic toward the bacteria. Chemical analysis for the detection of organic

Application of Biotests

211

compounds (volatiles and those extracted with dichloromethane) identified trichloroethylene (274 mg L-1) and tetrachloroethylene (1.6 mg L-1) in a sample from Brzeg Dolny. Since the EC50 of trichloroethylene is 176 mg L-1, it is highly probable that it was this compound that was mainly responsible for the poor surface water quality at Brzeg Dolny. No significant quantities of organic compounds were detected in the sample from the Mała Panew River. However, as the report by the Provincial Environmental Protection Inspectorate in Opole suggests (1997), the waters of the Mała Panew River were polluted with Zn and Pb compounds, the levels of which exceeded several times the permissible concentrations of these metals in surface waters. So, it was probably the high heavy metal content that was responsible for the observed toxicity of the water in the Mała Panew River. In a project to examine the influence of selected landfill sites in the province of Pomerania (Pomorze) in northern Poland on the ecotoxicity of groundwaters,114 ecotoxicological tests were performed on groundwater samples taken from monitoring piezometers located around seven of the largest and oldest (without insulation) landfill sites. The project included an acute toxicity test with V. fischeri bacteria as well as acute and chronic toxicity tests with Daphnia magna crustaceans. The groundwater samples from one of the piezometers located at a landfill site that also received waste from pharmaceutical companies were highly toxic; but the reason for this was not explained by any of the monitored chemical parameters. Additional chemical tests identified the presence of chlorobenzene, aniline, and dibutyl phthalate. The concentration of aniline was high (approximately 0.5 mg L -1).

9.7.2

IDENTIFICATION OF HOT SPOTS (SITES WITH A VERY HIGH LEVEL OF POLLUTION)

From the point of view of environmental management, it is very important to identify sites characterized by significant changes (compared with natural ecosystems) caused by the presence of primary or secondary pollutants. To identify the threats due to these changes, the range of influence of pollutants, the distribution of pollution intensity, and the directions and dynamics of changes need to be determined. The results of physicochemical studies are not a suitable tool with which to achieve this aim for the following reasons: • The limited information potential of studies of physicochemical parameters (there is a finite number of determined parameters) • The frequent lack of knowledge about secondary pollution • Problems with identifying the effects due to the synergistic interactions of pollutants • The different bioavailabilities of the toxic substances determined Ecotoxicological studies appear to be the most informative and cost-effective tools for the identification of pollution hot spots. The EUROCAT project115 involved the determination of acute toxicity in the waters of the Gulf of Gdan´sk with V. fischeri. Sea water samples were collected in four series and did not show any toxic effects, but the water samples collected in the final reaches of the Vistula River, near the bridge at Kiezmark (some 12 km upstream of the river mouth) and in the area where the river water merges with the sea showed a 30–60% decrease in luminescence. Considering the direction in which the gulf waters circulate (new water flows in from the northwest) and the fact that the Vistula River receives pollution from its entire catchment area, the results are not surprising. They show that the waters of the river are polluted with toxic substances; at the river mouth, after mixing with the waters of the gulf, there is a slight decrease in their toxicity. As a result of the northwesterly inflow of water into the gulf, the polluted river waters are directed to the east. In a pilot project on the monitoring and assessment of the quality of the waters of the Bug River where it forms the eastern border of Poland, tests were carried out to assess the acute and chronic toxicity of water samples taken from the river, sediment samples, and treated effluents reaching surface waters from the water treatment plants located in the river basin.116 Using a much simplified

212

Analytical Measurements in Aquatic Environments

classification system, resembling that used in the ARGE-Elbe project (a classification based on the PE), the quality of waters, sediments, and effluents were determined. Comparison of the results of ecotoxicological tests done on surface waters and effluents reveals a distinct link between the very low ecotoxicological quality of the effluents and the poor quality of surface waters near the point of discharge.

9.7.3

RANKING OF PROBLEMS IN POLLUTED AREAS MANAGED BY SPECIFIC AUTHORITIES

Solving environmental problems occurring in a given area usually requires considerable financial and human resources, not to mention suitable instruments and infrastructure. The availability of these resources is limited, hence it is necessary to rank the importance of problems and create corresponding lists of importance. The results of ecotoxicological studies may provide important and sometimes even key information permitting such sequences to be established. The examples given below illustrate well this potential of ecotoxicological studies. They assist in the choice of the most appropriate environmental decisions and help lower the costs of these decisions. Using a battery of tests consisting of five bioindicators (rotifers—Brachionus calyciflorus, bacteria—V. fischeri, crustaceans—Thamnocephalus platyurus and Daphnia magna, and duckweed— Lemna minor), ecotoxicological tests were conducted on effluents released into surface waters from water treatment plants located in the Bug River basin. Table 9.12 presents the results of toxicity determinations for the aforementioned organisms and the ecotoxicological quality of effluents according to the toxicity classes recommended by the HELCOM (TU)98–100 and toxicity classes using the pT value to assess the toxicity of the effluent.102,117 Comparison of the results obtained with these two systems of ecotoxicological classification (TU and pT) shows significant differences in the quality of the same samples; this is mainly because two of the bioindicators used in the project (Daphnia magna and V. fischeri), recommended the HELCOM system, are less sensitive than Brachionus calyciflorus and Thamnocephalus platyurus, used in the pT value system. Four or five of the water treatment plants participating in the project require further testing so that an explanation for the poor ecotoxicological quality of effluents can be found. In the project mentioned above, to assess the influence of selected landfill sites in the province of Pomerania (Poland) on the ecotoxicity of groundwaters,118 ecotoxicological tests were carried out on groundwater samples collected from monitoring piezometers around seven of the largest and oldest (without insulation) landfill sites. The study used the acute toxicity test for V. fischeri and the acute and chronic toxicity tests for Daphnia magna. The quality of groundwater was examined using three systems of ecotoxicological classification HELCOM (TU), Krebs (pT), and Persoone’s system.101 The groundwaters were also classified on the basis of physicochemical parameters, according to recommendations issued by the Polish Ministry of Environment.118 Comparison of the ecotoxicological quality of the examined samples with the physicochemical quality reveals distinct differences. Table 9.13 presents examples of two quite different situations, which arose during this comparison: • Piezometer P4: poor physicochemical quality (class 5) but good ecotoxicological quality. • Piezometer P6: very poor ecotoxicological quality of waters and poor physicochemical quality (class V). In the case of piezometer P4, the poor physiochemical quality was the result of admissible values for parameters such as turbidity, color, iron, and chloride being exceeded; but the ecological hazards posed by these excessive values are insignificant or nonexistent. The water monitored by piezometer P6 was assigned to quality class V (admissible values for the following parameters were exceeded: ammonia nitrogen, phenols, CODCr, CODMn, chloride, and total content of solutes); at the same time, however, the ecotoxicological quality of these waters was stated to be very poor. The slight excess of permissible values for the physiochemical markers does

PWiK Wyszków

b

a

TU, toxicity unit. Dump leachate near Tomaszów Lubelski.

Krebs classification (pT)

HELCOM classification (TU)

1.

(May 2003)

PWiK Wyszków

11.

PUiK Sokołów Podlaski

9.

PWiK Siedlce

PUiK Łuków

8.

10.

PGKiM Terespol

PWiK Biała Podlaska

NZPS Orchówek

5.

6.

MPGK Chełm

4.

7.

Piezometer no. 1

PGKiM Hrubieszów

2.

b

PGKiM Tomaszów Lubelski

3.

1.

8

8

64

—

64

128

64

128

64

64

64

TUa

(October 2001)

8

16

256

8

64

256

—

128

128

256

32

TUa

—Hazardous

—Unproblematic —Critical

3

4

>6

3

6

>6

0

>6

>6

>6

5

pT

Acute Toxicity (24 h)

Thamnocephalus platyurus

—Does not meet criteria

—Meets criteria

3

3

6

0

6

>6

6

>6

6

6

6

pT

Acute Toxicity (24 h)

Effluents

Brachionus calyciflorus

—

8

8

128

—

8

16

8

—

—

64

4

TUa

0

3

3

>6

0

3

4

3

0

0

6

2

pT

Acute Toxicity (48 h)

Daphnia magna

V. fischeri

8

3

3

3

3

3

3

3

3

6

5

3

TUa

3

1

1

1

1

1

1

1

1

3

2

1

pT

Acute Toxicity (30 min)

TABLE 9.12 Assessment of Toxicity from Water Treatment Plants According to the Krebs (pT) and HELCOM (TU) Classifications

Application of Biotests 213

214

Analytical Measurements in Aquatic Environments

TABLE 9.13

Ecotoxicological and Physicochemical Assessment of Undergroundwater Sample Collected from Piezometers118 HELCOM Piezometer 1

Krebs (pT)

Chemical Classification

Persoone

V. fischeri D. magna V. fischeri D. magna Wastewaters Undergroundwaters 2

3

4

Exceeded Parameters

5

6

7

8

9

10

11

P4 (10.11.2003)

Good

Good

I

0

III

50

II

50

V

P6 (07.12.2003)

Low

Low

III

VI

V

75

IV

83

V

Turbidity, color, iron, and chloride Ammonia nitrogen, phenols, CODCr, CODMn, chloride, total content of solutes

not explain such a poor ecotoxicological quality in the analyzed water samples. One problem did emerge from the results of the ecotoxicological studies, however, the solution to which required time-consuming and costly chemical analyses—chlorobenzene, aniline, and dibutyl phthalates were found to be present. This example shows how helpful information obtained from an ecotoxicological study can be in undertaking important decisions (related to the need to manage with limited financial resources).

9.7.4

REVISION OF MONITORING PARAMETERS

The assumption underlying the monitoring models used so far is that testing covers a certain range of parameters specified by legal regulations. Local discharges of other substances (not specified in the regulations) as well as secondary pollution effects remain “invisible” to the monitoring model and are not perceived as real environmental threats. The current provisions of the Water Directive (investigative monitoring) allow for further monitoring parameters to be added to the existing list. Toxicity studies can be particularly useful in this situation. A strict relationship should exist between toxicity (the average value of the indicated toxicity parameters in the case of the organism analyzed) and the monitoring parameter of the chemical load of the sediment sample (the total concentration of the indicated parameter in relation to the average value of this parameter across all the samples analyzed) (Figure 9.1). A condition of the appearance of such a relationship is that the spectrum of these physiochemical parameters mirrors the factors that actually pollute the environmental compartments under scrutiny and indicate toxicity in relation to biota. Monitoring of sediments from the Bug River basin indicates that they are not chemically polluted.119 Unfortunately, however, the relevant analyses did not take organic compounds into consideration; only the following were analyzed: • Heavy metals (Pb, Zn, Cr, Cu, Cg, Hg, Ni, and Co) • Macroelements (Fe, Mg, Al, and Mn) • Cations and anions (NH4+, Cl-, NO3-, NO2-, and SO42-) Examination of the relation between the toxicity parameters and the chemical load of the samples allows three separate groups of monitoring stations to be distinguished: • Three stations (Bug-Włodawa, Bug-Terespol, and Krzna-Neple), where the ecotoxicity was higher than expected owing to the high level of chemical pollution.

215

Application of Biotests

Chemical load (a.u.)

35 30 25

Bug-Nur

20 Bug-Włodawa

15 y = 0.5036x – 7.7706

10

R2 = 0.8036

Krzna-Neple Bug-Terespol

5 0

FIGURE 9.1 pollution.

0

10

20

30 40 50 Average toxicity (%)

60

70

80

Relationship between sediment toxicity in the Bug River basin and the level of chemical

• One station (Bug-Nur), where chemical loads were high but the toxicity low. • A cluster of stations (gray triangles in Figure 9.1), which indicates a linear relationship between the parameters determined and the toxicity of the sample (coefficient of determination R2 = 0.8036). The high level of chemical pollution in sediments at the Bug-Nur station was due to the Mg and Zn contents being twice as high as the average for the analyzed samples. Such a pollutant composition did not increase the toxicity of the sample. The particularly high toxicity of samples collected at the Bug-Włodawa, Bug-Terespol, and Krzna-Neple stations suggests that substances other than the ones monitored had an influence on the level of pollution in those samples. The monitoring parameters applied at these stations should be revised in order to make • An inventory of pollutants released into the water near these points • An independent attempt at identifying substances responsible for such a high toxicity in the analyzed samples The objective of another project was to evaluate the level of pollution in water and sediments in Lake Turawskie, a storage reservoir built in the 1930s on the Mała Panew River in southwestern Poland, and then to search for a correlation between the analytical chemical results and the toxicity parameters estimated from the application of biotests. Polluted waters as well as large amounts of polluted sediments enter the reservoir from the Mała Panew and its tributary, the Libawa. Industrial activities in the river basin include silver, zinc, and lead processing plants, steel and glass manufacture, and the production of cellulose and chemicals. Agriculture presents a further potential threat (e.g., fertilizer and pesticide run-off), as does the use of the reservoir’s banks for recreational purposes. Chemometric studies indicated a lack of correlation between individual chemical parameters and estimated toxicity parameters. A significant aspect of the toxicity effect is the bioavailability form in which a pollutant is present in the analyzed sample. Efforts were made to find a link between the toxicity of a sediment sample and the mobility of the heavy metal forms it contained, but no relationship could be found between the determined toxicity and the potential toxicity, the latter calculated on the basis of the load of mobile forms of metals. A relationship was found, however, between the determined toxicity effects using the crustacean Heterocypris incongruens and the potential toxicity resulting from total metal loads. These results indicate that forms of heavy metals that are insoluble in water may nonetheless be available to H. incongruens.

216

Analytical Measurements in Aquatic Environments

The Lake Turawskie analytical project confirmed the increased threat posed to the reservoir’s ecosystem by the unfortunate siting of a dump for postproduction sediments from the “Mała Panew” works in Ozimek (left bank, near the river’s point of entry to the lake). A more detailed explanation of how this dump will affect the environmental condition of Lake Turawskie will, however, require further study.

9.8 CONCLUSIONS Integration of chemical monitoring based on the measurement of each individual indicator of environmental pollution, including toxicity parameters, will yield fuller information regarding the state of an environmental compartment. Knowledge of all the possible biological effects that a given combination of pollutants will have in an ecosystem can be the basis for taking more accurately targeted administrative decisions and managing the environment more effectively. The possibility of including ecotoxicological studies in the monitoring of environmental pollution should therefore be considered. Beforehand, however, an appropriate classification of environmental samples will need to be prepared, a suitable ecotest chosen, and implementation tests conducted. The use of chemometric methods will cut the costs of environmental monitoring; in the future this can be carried out on the basis of an optimal number of indispensable parameters to be determined, without any loss of significant information on environmental pollution. A clear correlation between the results of chemical analysis and biotests is lacking, which precludes the separate application of these two types of tests. Ecotoxicological tests do, however, provide additional information on the state of the environment. They indicate the need for further, more detailed analytical studies, the aim of which should be to identify in samples those compounds not yet covered by current chemical monitoring programs, and whose presence in the environment is not yet controlled by any legal regulations on environmental protection. Polish and EU legislations suggest in directly that toxicity could be applied to assess the quality of the environment. However, there is a lack of knowledge and motivation enabling the routine application of biotests in environmental monitoring. Further analytical studies are therefore necessary before toxicity parameters can be included in environment quality assessment systems.

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Total Parameters as a Tool for the Evaluation of the Load of Xenobiotics in the Environment Tadeusz Górecki and Heba Shaaban El-Hussieny Mohamed

CONTENTS 10.1 10.2

Introduction .................................................................................................................... Biochemical Oxygen Demand, Chemical Oxygen Demand, and Total Organic Carbon .............................................................................................. 10.3 Total Parameters in Environmental Analysis ................................................................. 10.4 Conclusions ..................................................................................................................... References ..................................................................................................................................

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10.1 INTRODUCTION One of the unintended consequences of industrialization and urbanization is the global distribution of numerous chemicals throughout the atmosphere, hydrosphere, and lithosphere. Many of these compounds are xenobiotics, that is, they are foreign to living organisms.1 In the vast majority of cases, xenobiotics are considered to be environmental pollutants. They can be hazardous both to various ecosystems and to humans. One of the main tasks of environmental analytical chemistry is the analysis of those compounds in the environment. Environmental analytics has been the driving force for the development of many new or improved analytical methods. The growing concern regarding the potential harmful effects of long-term exposure to very low concentrations of some xenobiotics, especially those with carcinogenic properties, has resulted in an on-going demand for the determination of such compounds at ever decreasing levels and/or in increasingly complex matrices. This has led to the introduction of a number of new methods and instrumental techniques into analytical practice.2 One prominent example of such techniques is comprehensive two-dimensional gas chromatography (GC × GC).3,4 In this technique, samples are subjected to chromatographic separation in two columns coated with stationary phases of different selectivities. The columns are connected through a special interface (modulator), whose role is to collect the eluate from the first column and periodically inject it into the second, much shorter column. In the ideal case, analyte separation in the second column is completed before the next injection takes place. The cycle is repeated throughout the entire run. Compared to conventional, one-dimensional gas chromatography (1D-GC), GC × GC offers vastly improved separation power. Analytes that cannot be separated using any single column can often be baseline resolved using this technique. The number of analytes that can be resolved in a single GC × GC run is much 223

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higher than in 1D-GC because the peak capacity of a GC × GC system is to a first approximation the product of the peak capacities of the individual dimensions. In addition, GC × GC with thermal modulation offers significantly better sensitivity compared to 1D-GC owing to (a) band compression prior to reinjection into the second dimension, and (b) chromatographic separation of the first dimension column bleed from the analyte peaks in the second column. Taking these advantages into account, it should come as no surprise that GC × GC has found numerous applications in environmental analysis.5 Environmental analysis and monitoring are the foundation of all environmental science. Although they cannot solve any environmental problems by themselves, they do supply information on the condition of the environment, the effectiveness of remedial and preventive actions, and the impact of various technologies on the environment.6 Depending on the goals of the analysis and the method(s) used, environmental analysis can produce information of varying degrees of detail. In the simplest case scenario, only the elemental composition of the sample is determined, such as is often the case in inorganic analysis. Methods such as atomic absorption spectroscopy (AAS), inductively coupled plasma optical emission spectroscopy (ICP-OES), or inductively coupled plasma mass spectrometry (ICP-MS) yield exclusively this type of information (unless the final determination is preceded by analyte separation, as in the coupling of gas chromatography with atomic emission detection—GC-AED). At the other end of this spectrum is full speciation.7 According to the IUPAC definition, speciation analysis is a process leading to the identification and determination of the various forms of occurrence of a given element in a sample. There are two types of speciation analysis: physical speciation (the forms in which a chemical compound occurs) and chemical speciation (the identification and determination of all chemicals containing a given element). Numerous papers contain information on the particular types of chemical speciation (e.g., screening, distribution, group, chiral, or individual speciation). Taking into account the diversity of chemicals that can pollute a given environmental compartment (e.g., air, water, or soil), the separation, identification, and determination of all pollutants can be a daunting task with respect to both the complexity and the cost of the analysis. When full speciation is neither desirable nor necessary, and the information delivered by elemental analysis is insufficient, the third option is to determine a suitable total (or summary) parameter(s) describing the total content of a given element in all the pollutants or in a particular subgroup of pollutants.6 In some cases, the use of suitable total parameters could significantly reduce the number of necessary determinations, thereby allowing more efficient assessment of the degree of pollution. Both approaches (speciation analysis and determination of total parameters) should be considered complementary—the value of a suitable total parameter could be used to decide whether full speciation analysis is in fact necessary.

10.2

BIOCHEMICAL OXYGEN DEMAND, CHEMICAL OXYGEN DEMAND, AND TOTAL ORGANIC CARBON

Biochemical oxygen demand (BOD) is arguably the oldest total parameter used for the characterization of water quality. It was introduced in the first decade of the twentieth century as a test for the organic pollution of rivers. BOD is the amount of oxygen in mg L -1 required for the oxidation of the organic matter contained in water by biological action under standardized test conditions (usually a temperature of 20°C and an incubation time of 5 days).8,9 The test is often used to evaluate the efficiency of wastewater treatment processes. In the classical method of BOD determination, dissolved oxygen (DO) is determined in the sample using titration before and after the incubation period. The sample is introduced to a flask and diluted to a predetermined volume with distilled water. The flask is shaken to make sure that the water is saturated with oxygen. The pH of the sample is adjusted if necessary, and the covered flask is stored for the duration of the incubation period away from light. A blank sample is prepared in the same way. BOD is calculated as the difference between the initial DO content and the content after

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the incubation period, taking into account the dilution factor. When the typical incubation period of 5 days is used, the parameter determined is denoted BOD5. The limit of detection of this method is ~1 mg L-1. Determination of BOD is based on the measurement of DO consumed in the process of biodegradation of organic matter in a certain period of time. It is a universal parameter, the determination of which does not require expensive equipment. On the other hand, only compounds that undergo biodegradation contribute to BOD—refractory organic compounds cannot be detected by this technique. Reproducibility of this measurement is usually quite poor, and the method is very timeconsuming. A number of alternative approaches have been proposed to overcome this last limitation, including respirometric methods, headspace BOD determination, and direct measurement of absorbance.8 Another interesting alternative is the use of microbial BOD sensors.10 Such sensors consist of an immobilized microbial film sandwiched between two gas-permeable membranes. The response of the sensor is related to the change in the concentration of DO caused by biodegradation of the organic matter in the sample by the biofilm. A physical transducer is used to monitor this process. BOD biosensors measure short-term BOD, which is not necessarily identical to the conventional BOD5. Consequently, correlations between the two parameters need to be examined. Due to their short response times, BOD biosensors are particularly useful for control purposes during aerobic treatment of wastewaters. An alternative parameter that can be used to characterize the organic load of water is chemical oxygen demand (COD). COD is the amount of oxygen required to oxidize the organic matter present in the sample using chemical methods.8 In a COD assay, a known excess of a strong oxidizing agent (typically potassium dichromate under acidic conditions) is added to the sample and incubated with it for a period of time. Excess oxidant is then determined, usually by titration. COD determination is much faster than BOD determination—it can usually be completed in a few hours. In addition, the method is simpler and more reproducible than BOD determination. The values of COD and BOD for a given sample are usually correlated, although the exact correlations may vary widely from one sample to the other. COD values are usually greater than the corresponding BOD values because COD is related to the concentration of all oxidizable chemicals, whereas BOD is determined by the concentration of biodegradable chemicals only. The limitations of both BOD and COD determination can be overcome by direct determination of the organic carbon (OC) content of the sample. The corresponding parameter is called total organic carbon (TOC). It is defined as the amount of carbon covalently bonded in organic compounds in a water sample.8 The analytical value of TOC was recognized since 1931. A large number of papers dealing with the instrumental and methodological aspects of TOC determination in samples of various kinds have been published since then. TOC is a convenient measure of the overall contamination of water with organic compounds. It can also be a very useful measure of the efficiency of water and wastewater treatment. In both TOC and dissolved organic carbon (DOC) determinations, OC in the water sample is oxidized to produce carbon dioxide (CO2), which is then measured by a detection system. Inorganic carbon (IC) is removed prior to the analysis by acidifying the sample. Alternatively, TOC can be determined indirectly through the measurement of total carbon (TC) and IC. TOC in the indirect method is calculated as the difference between the two. There are two main approaches to the oxidation of OC in water samples to CO2: combustion in an oxidizing gas and UV-promoted or heat-catalyzed chemical oxidation. Other approaches are sometimes used, but are much less widespread.11 Carbon dioxide, which is released from the oxidized sample, can be detected in several ways, including conductivity detection, nondispersive infrared (NDIR) detection, or conversion to methane and measurement with a flame ionization detector (FID).12,13 The limits of detection in TOC determination can be as low as 1 μg L -1, and the dynamic range can span many orders of magnitude. The precision of the method is usually very good, and the analysis can be completed in a few minutes. Another advantage is the very small amount of sample required—from 10 to 2000 μL.

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The TC content of a sample can be subdivided into many fractions depending on the particular needs. The classification is often based on purely operational parameters, for example, the method used to release the carbon from the sample (examples include purgeable organic carbon—POC or acid-released organic carbon—AROC). Table 10.1 lists examples of the different fractions of TC that can be determined in liquid and solid samples. This particular classification is based on the determination of carbon content, but similar classifications could be prepared for other elements present in the pollutants. The TOC content can also be determined in air. However, the parameter used in this case is called total hydrocarbons (TH) rather than TOC. One significant difference between the OC in air and in other matrices is that the atmosphere contains a nearly constant background concentration of methane (~1.7 mg g-1 v/v),14 derived mostly from natural sources. Thus, any TH measurement will

TABLE 10.1 TC Fractions in Liquid and Solid Samples11 Parameter

Symbol

Organic carbon Inorganic carbon Liquid matrix Total carbon

OC IC TC

Total inorganic carbon

TIC

Dissolved inorganic carbon Particulate inorganic carbon Total organic carbon

DIC PIC TOC

Dissolved organic carbon

DOC

Particulate organic carbon

POC

Volatile organic carbon

VOC

Purgeable organic carbon

POC

Acid-released organic carbon Nonpurgeable organic carbon

AROC NPOC

Nonvolatile organic carbon Nonpurgeable dissolved organic carbon Nonvolatile dissolved organic carbon Solid matrix Total carbon

NVOC NPDOC NVDOC TC

Total inorganic carbon Total organic carbon Volatile organic carbon Nonvolatile organic carbon Acid-soluble organic carbon

TIC TOC VOC NVOC ASOC

Acid-insoluble organic carbon

AIOC

Oxidizable carbon Soil organic matter

OXC SOM

Description

All carbon present in any particle and compound TC = TIC + TOC All IC present in the form of carbonate, bicarbonate, and dissolved CO2. Quantity depending on pH, temperature, and partial pressure of CO2 TIC = DIC + PIC Suspended particle material All carbon from all organic sources covalently bound TOC = DOC + POC or TOC = NPOC + VOC All organic species that are soluble or pass through a filter of 0.45 μm DOC = VOC + NPDOC Suspended particles, moieties that are kept back by a 0.2–10 μm filter Low boiling (<100°C), low-molecular-weight compounds OC released by sparging. POC and VOC are often used interchangeably OC released by acid treatment Not removed by sparging NPOC = NPDOC + POC

All in solid form TC = TIC + TOC

Might be lost during separation of the spent acid (up to 45%). Increases roughly with the percentage of CaCO3 in the sample TOC = AIOC + ASOC Easily oxidizable OC, not stabilized in organic–mineral complexes Organic materials that accompany soil particles through a 2 mm sieve

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TABLE 10.2 Parameters and Techniques Used for the Determination of TH in Air6 Parameter TH

TNMHC

Measurement Technique Air is supplied directly to an FID

CO and CO2 are removed from the air, which is then directed through a suitable catalyst to a nondispersive infrared detector (NDIR) After removing CO and CO2, air is directed to an FID through a suitable catalyst (to oxidize organic compounds to CO2) and a methanizer (metallic nickel heated to 400°C, facilitating conversion of CO2 to CH4 in the presence of hydrogen) Air is directed to an FID either directly or through a catalyst capable of selective oxidation of nonmethane hydrocarbons. TNMHC is determined as the difference between the two signals (TH–CH4) A chromatographic column separates CO, CO2, and CH4 from other sample components. The three gases are detected by an FID after passing through a methanizer. The remaining organic compounds trapped at the column head are backflushed to the detector as a single peak Air is passed through a cryotrap, where all organic compounds except CH4 are selectively trapped. The analytes are injected to the detector by rapid heating of the trap Air passes through a catalytic reactor, where CO is selectively oxidized to CO2, a CO2 trap, and another catalytic reactor, where organic compounds (except CH4) are selectively oxidized. The CO2 formed (equivalent to TNMHC) is trapped using molecular sieves. Its amount can be determined using various techniques following thermal desorption

Comments Detector signal is not always proportional to the number of carbon atoms (e.g., due to the presence of heteroatoms). Methane concentration in the air is much higher than the total concentration of the remaining hydrocarbons, which makes it difficult to monitor changes in the levels of the latter Detector signal is proportional to the number of carbon atoms. Sensitivity is poor Very good sensitivity

Finding a suitable catalyst is a problem

Chromatographic determinations are discontinuous by nature

Ice formation inside the trap is a serious problem The procedure is very complex and error-prone due to its multistage character

include methane in addition to other hydrocarbons. A different parameter, total nonmethane hydrocarbons (TNMHC), can be used to eliminate this background contribution of methane. Table 10.26 contains a brief description of the techniques used for determining TH and TNMHC in air.

10.3

TOTAL PARAMETERS IN ENVIRONMENTAL ANALYSIS

Although detailed speciation analysis is gaining significance in environmental analytics, a large number of total parameters are still being used for the more general characterization of environmental samples. For example, the US Environmental Protection Agency (US EPA) specifies methods for the determination of the following total parameters among the 9000 series subset of methods for method SW-84615: Total and Amenable Cyanide (methods 9010C and 9012B), Total Organic

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Halides (TOX, methods 9020B and 9022), Purgeable Organic Halides (POX, method 9021), Extractable Organic Halides (EOX, method 9023), Acid-Soluble and Acid-Insoluble Sulfides (methods 9030B and 9034), Extractable Sulfides (method 9031), Sulfates (methods 9035, 9036 and 9038), Total Organic Carbon (method 9060A), Phenolics (methods 9065, 9066 and 9067), n-Hexane Extractable Material (HEM, method 9071B), Total Recoverable Petroleum Hydrocarbons (method 9074), Total Chlorine in Petroleum Products (methods 9075, 9076, and 9077), and Total Coliform (methods 9131 and 9132). All these methods are based on different principles, but a feature they have in common is that the total content of a given element or species is determined rather than the individual chemicals (or organisms in the case of Total Coliform) contributing to the parameter. Some of those parameters are subsets of other parameters (e.g., POX in the case of TOX), which allows for a somewhat more detailed characterization of the samples under study. This differentiation is typically based on the physical properties of the contributing analytes and the corresponding methods used to recover them from the samples. For example, TOX characterizes the total content of organic halides in water. It detects all organic halides containing chlorine, bromine, and iodine that are adsorbed by granular activated carbon under the conditions of the method (fluorinecontaining species are not determined).16 In this method, a sample of water free of nondissolved solids is passed through a column containing 40 mg of activated carbon. The column is washed to remove any trapped inorganic halides and the activated carbon is then combusted to convert the adsorbed organohalides to hydrogen halides (HX), which are trapped and titrated electrolytically using a microcoulometric detector. POX, on the other hand, allows the determination of volatile organic halides only. In this method, volatile organic halides are purged into a pyrolysis furnace using a stream of CO2. The HX formed during the pyrolysis of volatile analytes containing halogen atoms is trapped and titrated electrolytically with a microcoulometric detector.17 Finally, EOX is used to determine organic halides in solids. While this parameter is clearly aimed at determining the total content of organic halides in solids, its name reflects the fact that one can never be sure whether all the relevant analytes could be recovered from the sample using liquid extraction. In EOX determination, an aliquot of a solid sample is extracted with ethyl acetate by sonication to isolate organic halides. A 25 mL aliquot of the extract is introduced into a pyrolysis furnace using a stream of CO2/O2, and the HX pyrolysis product is determined by microcoulometric titration.18 The number of different total (summary) parameters that can be used in environmental analysis and monitoring is very large. For illustration, Table 10.36 lists examples of various parameters used by researchers to characterize gaseous, liquid, and solid samples, published between 1978 and 2000. Table 10.3 is followed by a brief literature review covering mostly research published in the last decade. The review is not intended to be comprehensive—its main goal is to illustrate that total parameters are still valuable tools in environmental analytics, in spite of the rapid development of ever more powerful chemical speciation methods and techniques. Total volatile organic carbon (TVOC) was determined in indoor air using an adsorption/ combustion-type gas sensor.103 The TVOC concentration was obtained from the detector output based on the different responses obtained for two different adsorption periods of the sensor; the output increased with increasing concentration of toluene as a typical VOC. An adsorption/combustion-type TVOC gas sensor with a low heat capacity employing Pd/g-Al2O3 as a sensing material fabricated on a silicon substrate was developed.104 The sensor was driven by low–high pulse heating at temperatures of 200°C and 400°C. Total volatile organic compounds were determined in ambient air using gas chromatography-mass spectrometry (GC-MS) following active collection on multisorbent tubes and thermal desorption.105 Unidentified analytes were quantified as toluene equivalents. Total sulfur (TS), acid-volatile sulfide (AVS), Cr-reducible sulfur (CRS), and extractable sulfate in sediments were determined by coulometric titrimetry,106 a method that yielded improved data quality and increased laboratory throughput. Total mercury, inorganic mercury, and methylmercury in water were determined using a simple and ultrasensitive method, based on cold vapor generation (CVG), coupled to atomic fluorescence

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TABLE 10.3 Examples of Total Parameters Used in Environmental Analysis and Monitoring6 Total Parameter

State of Aggregation Gaseous samples

Sample Origin Atmospheric air Indoor air Atmospheric aerosols Suspended particulate matter

Suspended particulate matter Exhaust gases

Liquid samples

Exhaust gas from waste incinerator Landfill gas Liquid samples Liquid samples Aqueous samples Aqueous samples Aqueous samples Ultrapure water Geothermal waters Aqueous samples Water Water Water Aqueous solutions Groundwater Groundwater Groundwater Surface water River water River water

River water River water

Name

Acronym

Total hydrocarbons Total volatile organic compounds Organic carbon Elemental carbon Elemental carbon Total soluble organic carbon Total insoluble organic carbon Total carbon Total organic halogens Volatile total organic halogens Extractable organic halogens

TH TVOC OC EC EC TSOC TSIC TC TOX VTOX EOX

Total sulfur Chemical oxygen demand Adsorbable organic sulfur Adsorbable organically bound elements Total organic carbon Purgeable organic halogens Total organic carbon Total mercury Adsorbable organic halogen Suspended organic carbon (particulate organic carbon) Total dissolved nitrogen Dissolved organic nitrogen Assimilable organic carbon Dissolved organic sulfur Total organic halogen Dissolved organic carbon Purgeable organic carbon Volatile halogenated hydrocarbons Total sulfur Organically bound sulfur Dissolved organic carbon Dissolved organic carbon Suspended organic carbon (particulate organic carbon) Dissolved organic nitrogen Suspended organic nitrogen Adsorbable organic halogens Dissolved total carbohydrates Dissolved free monosaccharides Dissolved organic carbon Biodegradable dissolved organic carbon Humic substances

TS COD AOS AOE TOC POX TOC AOX SOC (POC) TDN DON AOC DOS TOX DOC POC VHH TS OBS DOC DOC SOC (POC) DON SON AOX DTCH DFMS DOC BDOC

Reference 19 20 21

22 23 24 25 26 27 28–30 31 32–37 38 39,40 41 31,42,43 44 45 46 47 48,49 50–54 55 56 57–59 60

61,62 63

HS continued

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TABLE 10.3 State of Aggregation

Analytical Measurements in Aquatic Environments

(continued) Total Parameter Sample Origin River and lake water

Seawater Seawater Seawater Seawater Wastewater Wastewater Wastewater Wastewater Wastewater and process water Hospital wastewater

Solid samples

Surface water and seawater Soil Soil and sediments Sediments

Sediments Marine sediments Marine sediments Marine sediments Marine sediments and biota Lake sediments Lake sediments Sewage sludge Sewage sludge

Electronic waste Incineration residue Particulates from waste incineration

Name Total organic carbon Dissolved organic carbon Suspended organic carbon Total nitrogen Dissolved organic nitrogen Dissolved inorganic carbon Dissolved organic carbon Total organic carbon Adsorbable organic halogens Dissolved organic carbon Adsorbable organic halogens Total organic carbon Total nitrogen Total organic halogens Extractable organic halogens Purgeable organic halogens Total petroleum hydrocarbons Organic chlorine Water-soluble organic carbon Chemical oxygen demand Total nitrogen Total phosphorous Difference on ignition Organic carbon Total nitrogen Difference on ignition Total organic carbon Dissolved organic carbon Extractable organic halogens Extractable organic halogens Adsorbable organic halogen Total organic carbon Total organic carbon Chemical oxygen demand Biochemical oxygen demand Organic carbon Total organic halogens Elemental carbon Total organic carbon Extractable organic halogens

Acronym TOC DOC SOC TN DON DIC DOC TOC AOX DOC AOX TOC TN TOX EOX POX TPH Clorg WSOC COD TN TP DOI Corg Ntot DOI TOC DOC EOX EOX AOX TOC TOC COD BOD OC TOX EC TOC EOX

Reference 64–67

68 69 70 71–75 76 77,78 79 80,81 82 83

84 85.86 87 88

89 90 91 92 93,94 95,96 97 98 99

100 101 102

spectrometry (AFS).107 In the presence of UV irradiation, all the mercury (MeHg + Hg2+) in a sample solution was reduced to Hg(0) by SnCl2; in the absence of UV irradiation, only Hg2+ species could be determined. Total Hg and inorganic Hg were also determined by a novel method based on the on-line coupling of high-intensity focused ultrasound (HIFU) with a sequential injection/flow injection

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analysis (SIA/FIA) system.108 This method provided high throughput, automation, and low reagent consumption. Total mercury was determined in wastewater by cold-vapor atomic absorption spectrometry in an alkaline medium using sodium hypochlorite solution.109 This technique was simple and rapid because no digestion was required for the determination. The time required for the complete procedure was only about 5 min. Inorganic and organic Hg were also determined in wastewaters using cold-vapor atomic absorption spectrometry and pyrolysis atomic absorption spectrometry.110 Sample digestion was not required; inorganic Hg was directly determined by the cold vapor method, and total Hg was determined by the pyrolysis method. The value of total organic Hg was obtained as the difference of the two values. Total inorganic mercury was determined together with organomercury species in sediments using solid-phase microextraction and multicapillary GC hyphenated to inductively coupled plasma-time-of-flight mass spectrometry.111 Headspace solid-phase microextraction with a carboxen/polydimethylsyloxane fiber was used for the extraction/preconcentration of mercury species after derivatization with sodium tetraethylborate and subsequent volatilization. Total mercury in sewage sludge was determined using solid sampling Zeeman atomic absorption spectrometry,112 where a specially designed furnace was used and atomization of mercury was performed at a constant temperature in the 900–1000°C range. The method allowed the measurement of very low Hg concentrations without extraction or preconcentration procedures. Humic substances (HS) were determined in water using catalytic cathodic stripping voltammetry (CSV).113 This method was based on the adsorptive properties of iron–HS complexes on the mercury drop electrode at natural pH. HS were also determined in water using a method based on the binding of a dye, Toluidine Blue (TB), to HS molecules to produce a dye–HS complex, which caused a decrease in absorbance at 630 nm.114 The method was rapid, sensitive, and practicable. Total phosphorus in water was determined using FIA,115 on-line microwave digestion and flow injection spectrophotometry,116 and digital imaging colorimetry.117 In the last method, the interaction of potassium dihydrogen phosphate with ammonium molybdate, potassium antimonyl tartrate, and ascorbic acid in acidic media resulted in a blue complex. With increasing potassium dihydrogen phosphate concentration, the color of the solution and the RGB value of digital imaging increased. An electrochemical method based on using a nano-TiO2-K2S2O8 film for photocatalytic oxidation with PMo12 film-modified electrode was also used for the determination of total phosphorus in water.118 Total nitrogen was determined in water using high-temperature oxidation and chemiluminescence,119 as well as microwave digestion-UV spectrophotometry.120 Total nitrogen in solid waste was determined by modified Kjeldahl–Nessler reagent colorimetrically and modified Kjeldahl titration with hydrochloric acid.121 No significant differences were found between the two methods in terms of accuracy and precision. Extractable organic halides (EOX; also known as extractable organohalogens) together with extractable organochlorinated (EOCl), extractable organobrominated (EOBr), and extractable organoiodinated (EOI) compounds were determined in air by instrumental neutron activation analysis (INAA) combined with organic solvent extraction.122 EOX in sediments were assayed coulometrically; samples were extracted with n-hexane in a Soxhlet apparatus.123 EOX was determined in contaminated soils and sediments using two mixed solvents—toluene/n-hexane and acetone/n-hexane—as extractants.124 COD was determined in water using photoelectro-synergistic catalysis (PEC) with FIA125 and an on-line monitoring system based on the photoelectrochemical degradation principle. The latter method employed a specially designed thin-layer photoelectrochemical cell that incorporated a highly effective nanoparticulate TiO2 photoanode;126,127 it allowed direct quantitation of electron transfer at the TiO2 nanoporous film electrode during exhaustive photoelectrocatalytic degradation of organic matter in a thin-layer photoelectrochemical cell. The method was environmentally friendly, robust, and rapid, and did not require the use of a standard for calibration. COD was also determined in water by using a sensitive spectrophotometric method based on the use of a nanoTiO2-KMnO4 photocatalytic oxidation system128 and by using an electrochemical sensor with an

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electrode-surface grinding unit,129 where the oxidizing action of Cu on an organic species was used as the basis of the COD measurement. BOD was determined in wastewater using a microbial sensor based on an organic–inorganic hybrid material for immobilization of the biofilm. The biosensor response to the sample exhibited good reproducibility, long-term stability, and required only 10 min for each measurement.130 Nearinfrared spectroscopy was used for the rapid determination of COD and BOD in wastewater.131 Reference filters for the analysis of elemental carbon (EC) and OC in aerosol particles were produced by a spray-drying method and a carbon aerosol sampling system.132 Submicrometer carbon particles were produced by nebulizing a carbon black hydrosol and a potassium hydrogen phthalate solution. The TC concentration measured at three different locations on the filter showed that the carbon particles were uniformly distributed on the filter. EC and OC were also determined in snow and ice using a two-step heating GC system.133 OC and EC were transformed into CO2 in a stream of oxygen at 340°C and 650°C, respectively. The resulting CO2 was accumulated in two molecular sieve traps, and then introduced into a gas chromatograph by heating the traps to 200°C in a helium stream. Assimilable organic carbon (AOC) was determined in water using flow-cytometric enumeration and a natural microbial consortium as inoculum.134 Two bacterial species were used for the measurement of AOC in water, based on their respective 16S rDNA sequences. The AOC content in 41 water samples was determined with these two sets by quantitative real-time polymerase chain reaction (qRT-PCR).135 Total organic halogens (TOX), including TOCl, TOBr, and TOI, were determined in drinking water using pyrolysis and off-line ion chromatography.136 TOX and total volatile organic halogen (TVOX) were determined in exhaust gases using a method based on the adsorption of gaseous organohalogen compounds by a special-grade activated carbon.137 TOX was defined as the organohalogen compounds collected both in the water drain and in the activated carbon columns, whereas TVOX was defined as only the compounds collected by the activated C columns. The carbon particles were combusted in an electric furnace at 900°C. The HCl formed from the halogenated organics was determined by electrochemical titration. TOX determined by this method was proposed as an alternative index of dioxins in flue gas. TOX, EOX, AOX, and POX were determined in hospital waste sludge138 treated with 400 mg g-1 of hypochlorite. Ethanol is a solvent commonly used for extracting organic halides from sludge, but its extraction efficiency proved to be poor. Water-soluble organic carbon (WSOC) was characterized in atmospheric aerosols using solidstate 13C nuclear magnetic resonance (NMR) spectroscopy139 and anion-exchange chromatography.140 An instrument for the on-line measurement of WSOC was described, in which a particle-into-liquid sampler impacted ambient particles grown to large water droplets onto a plate, then washed them into a flow of purified water. The resulting liquid was filtered and the carbon content quantified by a TOC analyzer.141 TOC was determined in the neutral compound (NC), mono- and diacid (MDA), and polyacid (PA) fractions of WSOC in atmospheric aerosol particles using anion-exchange high-performance liquid chromatography.142 The method enabled direct TOC analysis of the eluted fractions without any pretreatment. Dissolved inorganic carbon (DIC) was determined in seawater using a method in which the seawater was acidified with 10% H3PO4; the evolved CO2 gas was absorbed by NaOH solution and titrated against HCl with the end points detected using phenolphthalein and a mixture of bromocresol green and methyl red.143 DIC and its isotope composition were determined in water using a gas chromatograph coupled to an isotope ratio mass spectrometer (GCIRMS). The instrument was capable of analyzing some 50 water samples per day.144 DIC and DOC were measured by sequential injection spectrophotometry with on-line UV photo-oxidation.145 Direct measurement of DIC in water was made possible by reagent-free ion chromatography (RF-IC)146 with an electrolytically generated hydroxide eluent. All inorganic forms of carbon were converted into carbonate, which was detected as a single chromatographic peak using conductivity detection.

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DOC was determined in water using an automated segmented flow analyzer,147 in which dissolved organic matter was converted to CO2 by UV-persulfate oxidation. The CO2 formed induced a change in pH that altered the color intensity of a phenolphthalein solution. The change was measured automatically by colorimetry. DOC and total dissolved nitrogen (TDN) were determined in water using a coupled high-temperature combustion TOC-nitrogen chemiluminescence detection system; this allowed the simultaneous determination of DOC and TDN in the same sample using a single injection and provided low detection limits and excellent linear ranges for both DOC and TDN.148 TC and total nitrogen were determined in soil using near-infrared spectroscopy.149 Thermal combustion combined with ion chromatography was used to measure TC in air particulate matter.150 OC, IC, and TC were determined in soil using a dual temperature combustion method, which enabled all three parameters to be obtained in a single run; the variability of this method was significantly reduced.151 DIC, OC, and TC were determined in natural waters using a combination of two methods: RF-IC and inductively coupled plasma atomic emission spectrometry (ICP-AES).152 DIC was measured in untreated samples using RF-IC and by in-line mixing with 0.1 M HNO3 to enhance CO2 removal in the nebulizer, followed by ICP-AES analysis. Total dissolved carbon (TDC) was measured by in-line mixing with 0.1 M NaOH followed by ICP-AES analysis. DOC was obtained as the difference between DIC and TDC. Only nonvolatile organic carbon could be detected with the method. The TS content was determined in waste activated sludge using microwave digestion followed by ICP-AES153 and by vacuum combustion extraction-quadrupole mass spectrometry (VCE-QMS).154 TS was determined in landfill gases by oxidative combustion followed by detection of the resulting SO2 with a quartz piezoelectric crystal microbalance (QCM).155 Dissolved organic sulfur was determined in aqueous solutions after isolation by solid-phase extraction on macroporous resins and reversed-phase sorbents.156 The sulfur in the extracts was determined by pyrohydrogenolysis of the extract in a heated quartz tube (1100°C) in a hydrogen atmosphere followed by flame photometric detection.

10.4 CONCLUSIONS Determination of total parameters is an example of activities classified as group speciation. Taking into account the sheer number and diversity of different chemicals that may be present in environmental samples, determination of total parameters could be an attractive alternative to full chemical speciation, especially for the initial screening of samples. Samples for which the value of a given total parameter exceeds prescribed limits can then be further analyzed using more advanced methods. Overall, group speciation can save both time and money in the characterization of environmental samples.

REFERENCES 1. IUPAC Compendium of Chemical Terminology, Electronic version. http://goldbook.iupac.org (2006), created by M. Nic, J. Jirat, B. Kosata; updates compiled by A. Jenkins. doi:10.1351/goldbook. 2. Namies´nik, J. 2000. Trends in environmental analytics and monitoring. Crit. Rev. Anal. Chem. 30: 221–269. 3. Górecki, T., J. Harynuk, and O. Panic´. 2003. Comprehensive two-dimensional gas chromatography (GC × GC). In: J. Namies´nik, W. Chrzanowski, and P. Zmijewska (eds), New Horizons and Challenges in Environmental Analysis and Monitoring, pp. 61–83. Gdan´sk (Poland): Centre of Excellence in Environmental Analysis and Monitoring, Gdan´sk University of Technology. 4. Górecki, T., O. Panic´, and N. Oldridge. 2006. Recent advances in comprehensive two-dimensional gas chromatography (GC × GC). J. Liquid Chromatogr. Rel. Technol. 29: 1077–1104. 5. Panic´, O. and T. Górecki. 2006. Comprehensive two-dimensional gas chromatography (GC × GC) in environmental analysis and monitoring. Anal. Bioanal. Chem. 386: 1013–1023. 6. Namies´nik, J. and T. Górecki. 2002. Application of total parameters in environmental analytics. Am. Environ. Lab. 34: 18–21.

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132. Lee, H.M., K. Okuyama, A. Mizohata, T. Kim, and H. Koyama. 2007. Fabrication of reference filter for measurements of EC (elemental carbon) and OC (organic carbon) in aerosol particles. Aerosol Sci. Technol. 41: 284–294. 133. Xu, B., T. Yao, X. Liu, and N. Wang. 2006. Elemental and organic carbon measurements with a two-step heating-gas chromatography system in snow samples from the Tibetan Plateau. Ann. Glaciol. 43: 257–262. 134. Hammes, F.A. and T. Egli. 2005. New method for assimilable organic carbon determination using flowcytometric enumeration and a natural microbial consortium as inoculum. Environ. Sci. Technol. 39: 3289–3294. 135. Zhang, T., X.L. Qin, and H.H.P. Fang. 2007. Use of P-17 and NOX specific primer sets for assimilable organic carbon (AOC) measurements. Water Sci. Technol: Water Supply 7: 157–163. 136. Hua, G. and D.A. Reckhow. 2006. Determination of TOCl, TOBr and TOI in drinking water by pyrolysis and off-line ion chromatography. Anal. Bioanal. Chem. 384: 495–504. 137. Kawamoto, K. 1999. TOX as a novel alternative index of dioxins in flue gas. Organohalogen Compd. 40: 157–160. 138. Tsai, C.T., C.T. Kuo, and S.T. Lin. 1998. Analysis of organic halides in hospital waste sludge disinfected using sodium hypochlorite (NaOCl). Water Res. 33: 778–784. 139. Sannigrahi, P., A.P. Sullivan, R.J. Weber, and E.D. Ingall. 2006. Characterization of water-soluble organic carbon in urban atmospheric aerosols using solid-state 13C NMR spectroscopy. Environ. Sci. Technol. 40: 666–672. 140. Chang, H., P. Herckes, J.L. Collett, and L. Jeffrey, Jr. 2004. On the use of anion exchange chromatography for the characterization of water soluble organic carbon. Geophys. Res. Lett. 32: L01810/1–L01810/4. 141. Sullivan, A.P., R.J. Weber, A.L. Clements, J.R. Turner, M.S. Bae, and J.J. Schauer. 2004. A method for on-line measurement of water-soluble organic carbon in ambient aerosol particles: Results from an urban site. Geophys. Res. Lett. 31: L13105/1–L13105/4. 142. Mancinelli, V., M. Rinaldi, E. Finessi, et al. 2007. An anion-exchange high-performance liquid chromatography method coupled to total organic carbon determination for the analysis of water-soluble organic aerosols. J. Chromatogr. A 1149: 385–389. 143. Song, J., X. Li, N. Li, X. Gao, H. Yuan, and T. Zhan. 2004. Simple and accurate method for determining accurately dissolved inorganic carbon in seawaters. Fenxi Huaxue 32: 1689–1692. 144. Assayag, N., K. Rive, M. Ader, D. Jezequel, and P. Agrinier. 2006. Improved method for isotopic and quantitative analysis of dissolved inorganic carbon in natural water samples. Rapid Commun. Mass Spectrom. 20: 2243–2251. 145. Tue-Ngeun, O., R.C. Sandford, J. Jakmunee, K. Grudpan, I.D. McKelvie, and P.J. Worsfold. 2005. Determination of dissolved inorganic carbon (DIC) and dissolved organic carbon (DOC) in freshwaters by sequential injection spectrophotometry with on-line UV photo-oxidation. Anal. Chim. Acta 554: 17–24. 146. Polesello, S., G. Tartari, P. Giacomotti, R. Mosello, and S. Cavalli. 2006. Determination of total dissolved inorganic carbon in freshwaters by reagent-free ion chromatography. J. Chromatogr. A 1118, 56–61. 147. Duarte, A.C. 2006. The assembling and application of an automated segmented flow analyzer for the determination of dissolved organic carbon based on UV-persulfate oxidation. Anal. Lett. 39: 1979–1992. 148. Pan, X., R. Sanders, A.D. Tappin, P.J. Worsfold, and E.P. Achterberg. 2005. Simultaneous determination of dissolved organic carbon and total dissolved nitrogen on a coupled high-temperature combustion total organic carbon-nitrogen chemiluminescence detection (HTC TOC-NCD) system. J. Autom. Meth. Manage. Chem. 4: 240–246. 149. Barthes, B.G., D. Brunet, H. Ferrer, J. Chotte, and C. Feller. 2006. Determination of total carbon and nitrogen content in a range of tropical soils using near infrared spectroscopy: Influence of replication and sample grinding and drying. J. Near Infrared Spectrosc. 14: 341–348. 150. Fung, Y.S. and K.L. Dao. 1998. Determination of total carbon in air particulate matters by thermal combustion—ion chromatography, Int. J. Environ. Anal. Chem. 69: 125–139. 151. Bisutti, I., I. Hilke, J. Schumacher, and M. Raessler. 2007. A novel single-run dual temperature combustion (SRDTC) method for the determination of organic, inorganic and total carbon in soil samples. Talanta 71: 521–528. 152. Stefansson, A., I. Gunnarsson, and N. Giroud. 2007. New methods for the direct determination of dissolved inorganic, organic and total carbon in natural waters by reagent-free ion chromatography and inductively coupled plasma atomic emission spectrometry. Anal. Chim. Acta 582: 69–74. 153. Dewil, R., J. Baeyens, F. Roelandt, and M. Peereman. 2006. The analysis of the total sulfur content of wastewater treatment sludge by ICP-OES. Environ. Eng. Sci. 23: 904–907.

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154. Sayi, Y.S., P.S. Shankaran, C.S. Yadav, G.C. Chhapru, K.L. Ramakumar, and V. Venugopal. 2002. Determination of total sulfur by vacuum combustion extraction-quadrupole mass spectrometry (VCEQMS). Proc. Natl. Acad. Sci. India Sect. A 72: 241–248. 155. Rocha, T.A.P., J.A.B.P. Oliveira, and A.C. Duarte. 1999. Determination of total sulfur in landfill gases using a quartz crystal microbalance. Int. J. Environ. Anal. Chem. 75: 121–126. 156. Binde, F. and H.H. Ruttinger. 1997. Isolation and determination of dissolved organic sulfur compounds. Development of the organic group parameter DOS. Fresenius J. Anal. Chem. 357: 411–415.

11

Determination of Radionuclides in the Aquatic Environment Bogdan Skwarzec

CONTENTS 11.1 Introduction ...................................................................................................................... 11.2 Determination of Radionuclides in the Aquatic Environment ......................................... 11.2.1 Primordial Radionuclide: 40K ............................................................................... 11.2.2 Neutron Activation Products: 55Fe and 63Ni .......................................................... 11.2.2.1 Determination of 55Fe and 63Ni .............................................................. 11.2.3 Fission Products: 90Sr and 137Cs ............................................................................ 11.2.3.1 Determination of 137Cs ........................................................................... 11.2.3.2 Determination of 90Sr ............................................................................. 226 11.2.4 Ra in Water ....................................................................................................... 11.2.5 222Rn in Water ....................................................................................................... 11.2.6 Natural and Transuranic Alpha Radionuclides: 210Po, 234U, 235U, 238U, 238Pu, 239+240Pu, and 241Pu ..................................................................... 11.2.6.1 Radiochemical Methods for Determination of Polonium, Radiolead, Uranium, and Plutonium in Aquatic Samples .............................................................................. 11.2.6.2 Coprecipitation of Polonium, Radiolead, Uranium, and Plutonium with Manganese Dioxide in Natural Waters ..................................................................................... 11.2.6.3 Mineralization of Suspended Matter ................................................... 11.2.6.4 Mineralization of Sediment ................................................................. 11.2.6.5 Mineralization of Biota ........................................................................ 11.2.6.6 Separation and Determination of Polonium 210Po and Lead 210Pb ............................................................................. 11.2.6.7 Separation, Purification, and Electrolysis of Plutonium ...................... 11.2.6.8 Separation, Purification, and Electrolysis of Uranium ........................ 11.2.6.9 Measurement of Radionuclide Activity ............................................... 11.2.6.10 Activity Determination of Polonium, Radiolead, Uranium, and Plutonium Radionuclides .............................................. 11.2.6.11 Determination of 241Pu Activity ........................................................... References ..................................................................................................................................

242 242 242 242 243 246 246 247 248 249 249

249

249 250 251 251 251 252 252 253 253 256 256

241

242

11.1

Analytical Measurements in Aquatic Environments

INTRODUCTION

The radionuclides present in the environment are classified as being either of natural or of anthropogenic origin1: Naturally occurring radionuclides a. Radionuclides of terrestrial origin (e.g., 40K and 87Rb) b. Cosmogenic radionuclides (e.g., 3H, 14C, 32Si, and 36Cl) c. Primary radionuclides: these long-lived radionuclides have been ubiquitous on the Earth ever since its formation, that is, approximately 4.5 × 109 years ago. The radionuclides 238U, 232Th, and 235U are the respective parent members of the uranium, thorium, and actinouranium radioactive decay series Anthropogenic radionuclides a. Neutron activation products (e.g., 22Na, 54Mn, 55Fe, 60Co, 63Ni, 64Cu, 65Zn, 110mAg, and 125Sb) b. 235U and 239Pu fission radionuclides (e.g., 90Sr, 95Zr, 131I, 132I, 132Te, 137Cs, and 144Ce) c. Transuranic elements (e.g., 237Np, 238Pu, 239Pu, 240Pu, 241Pu, 241Am, and 243Am)

124

Sb,

Because of their long half-life, type of decay, and strong radiotoxicity, the most important radionuclides in the aquatic environment are 40K (primordial radionuclide), 55Fe and 63Ni (neutron activation products), 90Sr and 137Cs (fission products), 210Po, 210Pb, 234U, 235U, and 238U (naturally occurring alpha and beta emitters), and 238Pu, 239Pu, 240Pu, and 241Pu (artificial plutonium radionuclides).1

11.2 11.2.1

DETERMINATION OF RADIONUCLIDES IN THE AQUATIC ENVIRONMENT PRIMORDIAL RADIONUCLIDE: 40K

The isotope 40K can be analyzed in natural water samples with the Cherenkov counting technique.2,3 Because of the lack of a suitable radiotracer for K and the similarity between the chemistries of rubidium and potassium, 86Rb can be used as a tracer for K.4 Also, thermal ionization mass spectrometry (TIMS) has been used to determine 40K in environmental samples. The interference of mass 40 can be solved by double spiking with 43Ca/48Ca; the procedure for the routine highprecision isotope analysis of the K–Ca system will then be free of Ca fractionations.5

11.2.2 NEUTRON ACTIVATION PRODUCTS: 55Fe AND 63Ni A number of artificial radionuclides are produced as a result of activation during nuclear weapons tests, the operation of reprocessing plants and reactors in nuclear power stations, and in nuclear studies. Novel radioanalytical techniques have enabled activation products such as 22Na, 51Cr, 54Mn, 65Zn, 110 mAg, and 124Sb to be detected in the environment.6,7 Stainless steel contains iron and nickel—important materials in nuclear power reactors and possible constituents of the materials used to construct nuclear test devices or their supporting structures.8,9 During nuclear weapons tests, stable Fe and Ni isotopes are neutron activated, giving rise to radioactive Fe and Ni along with fission products. In nuclear power plants, moreover, stable Fe and Ni isotopes are released from stainless steel through corrosion, become activated, and are transported to different parts of the reactor system. Neutron activation of the stable isotopes of iron produces two radioactive isotopes—55Fe and 59Fe. 55Fe (half-life = 2.685 years), which is a beta (electron-capture) emitter and decays to the stable 55Mn isotope, is the more important isotope.10

Determination of Radionuclides in the Aquatic Environment

243

The production of radioactive nickel isotopes through neutron activation yields 59Ni, 63Ni, and 65Ni. Of these three, 63Ni is important, because the activity ratio of 59Ni/63Ni is only 0.01.6 The 63Ni isotope is a beta-particle emitter with a half-life of 100.1 years, decaying to the stable 63Cu isotope.10 11.2.2.1 Determination of 55Fe and 63Ni The radioanalytical methods of determining 55Fe and 63Ni were worked out by Holm et al.6 and Skwarzec et al.11 Figures 11.1 and 11.2 illustrate the procedures for the radiochemical analysis of 55Fe and 63Ni in aquatic environmental samples. The radiochemical yield is determined by the atomic absorption spectrometry (AAS) of stable Fe and Ni before and after electrodeposition. The activities of 55Fe and 63Ni are measured using an anticoincidence-shielded windowless low-level beta-particle gas-flow counter operating in the Geiger–Müller region. The gas-flow counter is a four-channel counter from the Risø National Laboratory, Denmark, using argon (99%) and isobutane (1%) as the counting gas.11 11.2.2.1.1 Separation and Determination of 55Fe Figure 11.1 presents a scheme for the radioanalytical determination of 55Fe in water, biota, and sediment samples.11 This procedure is based on the separation of Fe from other metals (especially Cd, Cs, Cu, Ni, and Zn) on an anion exchange resin. The iron is then purified by coprecipitation with cupferron (the ammonium salt of nitrosophenylhydroxylamine). 11.2.2.1.2 Coprecipitation of 55Fe in Natural Water with Iron Hydroxide 11.2.2.1.2.1 Procedure 1 About 5–10 L of natural water is passed through a preweighed membrane filter of 0.45 mm pore diameter. The water is adjusted to pH ⬇ 9 with ammonia, and about 1 g of iron (FeCl3 solution) is added as radiochemical yield determinant. Nitrogen is bubbled for about 2 h to ensure good mixing and isotope exchange. The iron hydroxide Fe(OH)3 deposit is allowed to settle overnight; the overlying liquid phase is sucked off and the precipitate is collected by decantation. The precipitate containing 55Fe is dissolved in 20 mL 9 M HCl and the solution is passed through a column containing Dowex 1 × 4 (100–200 mesh) anion exchange resin. The 55Fe is then separated, purified, and electroplated according to procedure 2. 11.2.2.1.3 Mineralization, Separation, and Electrolysis of 55Fe in Aquatic Sediment and Biota Samples 11.2.2.1.3.1 Procedure 2 10 mL perhydrol (30% H2O2) is added to 10 g of a sediment or biota sample ashed for 12 h at 550°C and heated until the perhydrol is completely decomposed. After evaporation, 20 mL aqua regia is added to the dry residue; the sample is then heated for 1 h and evaporated to dryness. The dry residue is dissolved in 15 mL 9 M HCl and the solution is passed through a 0.8 mm pore diameter Sartorius membrane filter. The deposit retained on the filter is leached with 15 mL 9 M HCl and filtered again. The residue is added to the supernatant from the first filtration. 1 mL of the solution is diluted with distilled water and Fe determined by AAS. The remainder of the solution is passed through a column (100 × 10 mm2) containing Dowex 1 × 4 (100–200 mesh) anion exchange resin, after which the column is flushed with 50 mL 9 M HCl. The eluate and flushing solution (in 9 M HCl) are discarded. The Fe adsorbed on the resin is eluted using 30 mL 0.5 M HCl. 10 mg cupferron per 1 mg of iron is added to the solution, which is then stored overnight at temperatures between 0°C and 4°C. The resulting brown precipitate [(Cup)3Fe] is removed with a Sartorius membrane filter, and the cupferrate is decomposed with 50 mL aqua regia and 10 mL 65% HNO3. After evaporation, the dry residue is dissolved in 10 mL 4 M HCl. 1 mL of this solution is taken for the AAS measurement of stable Fe. The remainder of the solution is transferred to a plating cell and a “pinch” of ascorbic acid (reducing Fe3+ to Fe2+), NH4OH (pH = 9), and 5 mL 0.6 M (NH4)2SO4 (aq) are added. The Fe is electroplated on a polished copper disc (diameter = 17 mm) for 2 h with a current of 0.3 A. After electrodeposition, a known fraction of the electrolyte is again taken for an AAS measurement of stable iron.

244

Analytical Measurements in Aquatic Environments

Water sample

Sediment, soil, and biological material

Coprecipitation with Fe(OH)3

Ashing and mineralization

Sample in 9 M HCl

Filtration Precipitate

Leaching with 9 M HCl

Filtration Precipitate (discard) AAS

1 mL of solution Fe determination

Supernatant

Supernatant

1.50 mL 9 M HCl 2.30 mL 0.5 M HCl

Dowex 1 ¥ 4 1. Solution discard 2. Coprecipitation and filtration of iron cupferrate [(Cup)3 Fe]

Mineralization of [(Cup)3 Fe]

AAS

AAS

1 mL of solution Fe determination 1 mL of solution Fe determination

After evaporation dissolution in 4 M HCl

Electrolysis of Fe on copper disc

Addition of 5 mL 0.6 M (NH)2SO4

Measurement by b-spectrometry

FIGURE 11.1

Radioanalytical determination of 55Fe in aquatic samples.

11.2.2.1.4 Separation and Determination of 63Ni Figure 11.2 shows a scheme for the radioanalytical determination of 63Ni in aquatic samples.11 The method for determining nickel activity is based on the separation of this element from other radionuclides, particularly 55Fe. To separate 63Ni, the stable dimethylglyoxime (DMG) complex (DMG)2Ni is formed in ammonia and extracted with chloroform.

245

Determination of Radionuclides in the Aquatic Environment

Sediment, soil, and biological material 1 mL of solution

Water sample

AAS

Ashing and mineralization Ni determination

Coprecipitation with Fe(OH)3

Centrifugation

Supernatant Precipitate (discard) Complexation of (DMG)2 Ni

Extraction of (DMG)2 Ni complex with chloroform Aqueous phase (discard) Washing of organic phase with 1% NH4OH Aqueous phase (discard) Reextraction of Ni with 1.5 M HCl Aqueous phase (discard) Sediment from aqueous phase after evaporation dissolution in 9 M HCl 40 mL 9 M HCl

Dowex 1 ¥ 8

AAS

1 mL of solution Ni determination

AAS

1 mL of solution Ni determination

After evaporation dissolution in 0.6 M (NH)2SO4

Electrolysis of Ni on copper disc

Measurement by b-spectrometry

FIGURE 11.2

Radioanalytical determination of 63Ni in aquatic samples.

11.2.2.1.5 Separation of 63Ni in Natural Water from other Radionuclides by Coprecipitation with Hydroxide 11.2.2.1.5.1 Procedure 3 About 20–30 L of natural water is passed through a preweighed membrane filter of 0.45 mm diameter. The water is adjusted to pH ⬵ 9 with NH4OH, and about

246

Analytical Measurements in Aquatic Environments

200 mg of stable Ni is added as radiochemical yield determinant. Next, approximately 10 mL 1 M FeCl3 (aq) is added to the sample. Nitrogen is bubbled for about 2 h to ensure good mixing and isotope exchange. The iron hydroxide Fe(OH)3 precipitate is allowed to settle overnight and, after decantation, is discarded. The supernatant containing 63Ni is evaporated to dryness and the residue dissolved in 30 mL 1 M HCl. 63Ni is then separated, purified, and electroplated according to procedure 4. Mineralization, Separation, and Electrolysis of 63Ni in Aquatic Sediment and Biota Samples 11.2.2.1.6.1 Procedure 4 Approximately 50 g of sample (dry sediment or biological material) is ashed for 12 h at 550°C together with 200 mg stable Ni as radiochemical yield determinant. The sample is then leached with 50 mL aqua regia, the sediment centrifuged, and the supernatant evaporated to dryness. The residue is dissolved in 30 mL 1 M HCl and the hydroxides precipitated with NH4OH (pH ≥ 9) leaving Ni in the supernatant. After centrifugation, 15 mL 1% DMG in ethanol is added and the pink (DMG)2Ni complex formed is extracted with 3 × 30 mL chloroform. The organic phase is rinsed with 2 × 25 mL 1% NH4OH, and the Ni is backextracted with 2 × 25 mL 1.5 M HCl. The acidic aqueous phase is evaporated with a few drops of 65% HNO3 and the dry residue dissolved in 10 mL 9 M HCl. The solution is passed through a column (100 mm × 10 mm) containing Dowex 1 × 8 (100–200 mesh) anion exchange resin, and the nickel adsorbed on the resin is eluted with 40 mL 9 M HCl. The solution is evaporated to dryness and the residue treated with a small quantity of 65% HNO3 to destroy any organic matter. After evaporation, 1 mL conc. H2SO4 is added to the sample, which is then heated until white fumes appear. After the addition of 5 mL 0.6 M (NH4)2SO4, the sample is adjusted to pH ≥ 9 and the volume adjusted to 10 mL. 1 mL of electrolyte is taken for an AAS measurement of stable Ni. The rest of the solution is transferred to a plating cell. The distance between the electrodes can be adjusted by moving the platinum wire (anode) up to 5 mm. The nickel is electroplated on a polished copper disc (diameter = 17 mm) for 2 h at a current of 0.2 A with a few drops of NH4OH being added every 30 min. After electrodeposition, a known fraction of the electrolyte is again taken for an AAS measurement of stable Ni. 11.2.2.1.6

11.2.3

FISSION PRODUCTS: 90Sr AND 137Cs

11.2.3.1 Determination of 137Cs The artificial 137Cs radionuclide is one of the most important long-lived (T = 30.17 years) fission products and a common contaminant. It emits b-radiation of two energies—1176 keV (6%) and 514 keV (94%)—exciting a 2.55 min isomeric level of 137Ba*. This isomeric level de-excites itself by the emission of a single g-ray of 661.66 keV. In the equilibrium state, the activities of 137Cs and 137Ba* are the same.10 137Cs activity can be determined directly using beta spectrometry or indirectly by measuring the 137Ba* activity with gamma spectrometry (E = 662 keV).12,13 In aquatic samples, 137Cs determination is based on its adsorption on AMP (ammonium phosphomolybdate hydrate, (NH4)3PO4·12MoO3·3H2O) in water samples, the separation and purification of cesium on a cation exchange resin, coprecipitation of cesium hexachloroplatinate Cs2PtCl6, and measurement of 137Cs activity in a low-level flow beta counter.13 11.2.3.1.1 Separation of Cesium and Strontium by Adsorption on AMP 11.2.3.1.1.1 Procedure 1 About 30 L natural water is acidified to pH = 1 with 6 M HCl and approximately 50 mL 7.5 mM CsCl (aq) and 50 mL 0.15 M SrCl2 (aq) (both chemical recovery tracers) are added. After mixing, approximately 10 g AMP is added and nitrogen gas bubbled for about 0.5 h to ensure good mixing. The AMP precipitate with cesium is allowed to settle overnight; the overlying liquid phase containing strontium is collected for 90Sr determination; the AMP precipitate is filtered, and then rinsed with 0.05 M HCl. Next, the AMP sediment is dissolved in 20 mL EDTA (sodium ethylenediaminetetraacetate) and NaOH solution (32 g NaOH + 20 g EDTA L -1). After

247

Determination of Radionuclides in the Aquatic Environment

filtration, the solution is passed through a column (Ø = 10 mm; length = 120 mm) containing Dowex cation exchange resin. The column is flushed with 50 mL H2O, after which the cations (Na +, K+, and Rb +) adsorbed on the resin are eluted with 350 mL 0.3 M HCl. Finally, the cesium (Cs +) adsorbed on the resin is eluted with 120 mL 3 M HCl. The eluate is evaporated and the residue treated with a few drops of conc. HCl and conc. HNO3 to destroy any remaining organic matter and ammonia (NH4+). Next, a few drops of 6 M HCl and 5 mL distilled H2O are added to the dry residue; the resulting solution is cooled, and then added to 1 mL 0.22 mM of aqueous hexachloroplatinic acid (H2PtCl6). The cesium hexachloroplatinate (Cs2PtCl6) precipitate is filtered, dried, and weighed. The 137Cs activity in the precipitate is measured with a low-level flow beta counter. 11.2.3.1.2 Calculation of 137Cs Activity The calibration coefficient h between the mass of Cs2PtCl6 sediment and lated from A , h = ________ CPM100%

137

Cs activity is calcu-

(11.1)

where h is the calibration coefficient (Bq count-1 min-1) (usual range 0.03–0.06), A is the activity of Cs standard, and CPM100% is the number of counts calculated for 100% cesium recovery. The 137Cs activity in the samples is calculated from

137

CPMh ◊ h ◊ 100% C = _______________, m◊Y

(11.2)

where C is the 137Cs concentration (Bq L -1), m is the volume or sample mass (L), h is the calibration coefficient (Bq min-1 count-1), CPMh is the number of counts during 137Cs measurement with the beta counter (without background), and Y is the recovery (%). The standard deviation (SD) for activity of 137Cs is calculated from

SD =

CPM b CPM t + , tp tt

(11.3)

where CPMb is the number of counts including background during sample measurement with the beta counter, CPMt is the number of background counts with the beta counter, tp is the sample counting time, and tt is the background counting time. 11.2.3.2 Determination of 90Sr 90Sr is one of the most hazardous and dangerous radioactive isotopes. It is a pure beta emitter (Emax = 546 keV) and decays to another pure beta emitter, 90Y (Emax = 2283.9 keV).10 The radiochemical methods for determining 90Sr in aquatic samples (water, sediment, and biota) are based on the adsorption of radiostrontium on AMP in water samples, mineralization of sediment and biota, and sorption on Sr resin.14–16 11.2.3.2.1 Procedure 2 Before analysis, 85Sr is added to each sample as a chemical recovery tracer. 250 g oxalic acid C2H2O4 is added to the liquid phase (supernatant) containing strontium from the water samples (see procedure 1); the solution is stirred for 10 min, after which conc. NH4OH is added to bring the solution to pH = 7. After decantation of the supernatant, the oxalate precipitate is rinsed with distilled water, and then dissolved in 50 mL of a mixture of 3 M HNO3 and 0.01 M C2H2O4. Samples of aquatic organisms and sediments, after mineralization, are heated under watch-glass covers to boiling point and kept simmering for about 4 h. The Sr present in the sample is leached

248

Analytical Measurements in Aquatic Environments

into the solution. After cooling, the sample is filtered and the solid residue discarded. The solution is evaporated to dryness and redissolved in 50 mL of the 3 M HNO3 + 0.01 M C2H2O4 mixture. Next, strontium is separated on a chromatographic column filled with Sr resin. This column is conditioned with 50 mL of the 3 M HNO3 + 0.01 M C2H2O4 mixture. The sample solution is then poured into the column, followed by 20 mL of the 3 M HNO3 + 0.01 M C2H2O4 mixture as a flushing solution. Under such conditions the majority of the sample matrix passes straight through the column, whereas Sr is strongly retained. Strontium (also 90Sr) is then eluted from the column with 50 mL distilled water. This fraction may also contain traces of 210Pb. This nuclide and its daughter products 210Bi and 210Po decay by emitting beta and alpha particles, respectively; so if they are present in the sample, they may obscure the 90Sr signal during liquid scintillation counting. Therefore, an additional purification step has to be introduced to the procedure. The strontium fraction is evaporated to dryness with the addition of 10 mg Pb carrier in Pb(NO3)2 solution (1 mL). The evaporation is necessary to remove possible traces of nitric acid that may still be remaining in the sample after its elution from the column. The sample is then redissolved in 30 mL distilled water containing a few drops of CH3COOH (1:1) and 3 mL of NH4I (5 g/100 mL) solution is added. The yellow PbI2 precipitate is then dissolved by fi rst heating the sample and then recrystallizing it by cooling the beaker in a cold water bath. The solution is then suctionfiltered through a paper filter. The solid residue is discarded and the solution containing Sr evaporated to dryness with the addition of conc. HNO3 to remove excess iodine. After evaporation, the dry residue is dissolved in 1 mL 1 M HNO3 and transferred to a plastic liquid scintillation vial. The beaker is rinsed twice with 1 mL distilled water, which is then combined with the sample. This is then measured with a low-background gamma spectrometer equipped with an HPGe detector to determine the 85Sr activity in order to determine the chemical recovery. After 14 days, the sample containing 90Sr in equilibrium with its daughter 90Y is measured with a 1414-003 Wallac Guardian liquid scintillation counter. 11.2.3.2.2 Calculation of 90Sr Activity After measurement with the beta counter the 90Sr activity is calculated from 29.55 ◊ N ◊ 100% , A = ______________ 2 ◊ t ◊ eff ◊ Y ◊ m

(11.4)

where A is the 90Sr activity (Bq L -1), N is the number of counts, t is the counting time (s), Y is the recovery of 85Sr tracer (%) from gamma measurement, m is the volume or mass of sample (L or g), 29.55 is the proportionality factor between number of counts in 90Y and 90Sr–90Y spectral energy, 2 is the value of the activity of either 90Sr or 90Y—these two activities are in equilibrium, and eff is the effective factor for beta radiation (usually from 0.90 to 1.00). A eff = ___2 , A where A2 is the 90Y activity in sample and A is the real 90Y activity. The detection limit of 90Sr is calculated from17 _________

L d = 2.86 + 4.78√(B + 1.36) ,

(11.5)

where B is the number of background counts.

11.2.4

226

Ra IN WATER

Ra (half-life = 1602 years) is a naturally occurring radioisotope of the 238U decay series. Earth, marine, and environmental scientists often require analysis of 226Ra in natural water because of public health concerns18 and because it has proved to be a useful tracer of geochemical processes, 226

Determination of Radionuclides in the Aquatic Environment

249

particularly in the aquatic environment.19 The measurement of radium in natural, public, and drinking water supplies has become a matter of interest since it is one of the most hazardous elements with respect to internal radiation exposure20; indeed, the enforcement of regulations has made the analysis of 226Ra and 228Ra in ground water very common. Natural waters are by far the most frequent sample matrices assayed for radium by liquid scintillation methods,21,22 Cherenkov counting of its daughter nuclides23 and alpha measurement, and mass spectrometric analysis (ICP-MS).24

11.2.5

222

Rn IN WATER

Rn (half-life = 3.8 days) is an inert noble gas and the immediate daughter nuclide of 226Ra. Zikovsky and Roireau25 have developed simple methods for the measurement of radon in water using a proportional counter. The method is based on purging radon from water with argon, which is bubbled through the water sample and then directed to the counting tube. The argon picks up the radon that was dissolved in the water. A gas purification system removes moisture and oxygen. A high voltage is set for the alpha plateau; this gives a very low background of <0.2 cpm (counts per minute), a counting efficiency of 25%, and thus a detection limit of 0.02 Bq L -1. This limit compares favorably with that of other methods developed for the determination of radon in water, such as liquid scintillation,26 Cherenkov counting,27 or luminescence analysis.28 222

11.2.6

NATURAL AND TRANSURANIC ALPHA RADIONUCLIDES: 210Po, 234U, 235U, 238U, 238Pu, 239+240Pu, AND 241Pu

A number of natural and artificial alpha radionuclides are used, or could be used, as indicators for studying geochemical and biological processes in the natural aquatic environment. The concentrations of these radionuclides in natural components are very low. Thus, high-quality analytical procedures are needed for the measurement of radionuclides in environmental samples. Until now a large number of radioanalytical methods for either a single radionuclide or a limited number of radionuclides have been described in the literature. However, only a few methods are available for multiradionuclide determination.29-32 11.2.6.1

Radiochemical Methods for Determination of Polonium, Radiolead, Uranium, and Plutonium in Aquatic Samples The radiochemical procedure for the simultaneous determination of natural (210Po, 210Pb, 234U, and 238U) and artificial (238Pu, 239+240Pu, and 241Pu) isotopes in aquatic samples (water, sediments, and biological material) is based on the coprecipitation of radionuclides with manganese dioxide in natural water, the mineralization of sediment and biota samples, and the sequential separation and purification of radionuclides on anion exchange resins. The separated elements are electrodeposited on silver (polonium) or steel discs (uranium and plutonium), and their activities measured by alpha spectrometry with low-level-activity silicon detectors. The radiochemical analysis of aquatic samples (water, biota, and sediments) presented in Figure 11.3 enables polonium, radiolead, uranium, and plutonium to be determined, and ensures high recoveries as well.33,34 11.2.6.2 Coprecipitation of Polonium, Radiolead, Uranium, and Plutonium with Manganese Dioxide in Natural Waters 11.2.6.2.1 Procedure 1 About 20 L (analysis of polonium and uranium) or 100 L (analysis of plutonium) of natural water is passed through a preweighed membrane filter (with a pore diameter of 0.45 mm). The water is acidified to pH = 1 with 65% HNO3, and about 50 mBq of each of the tracers 209Po, 232U, and 242Pu are added. Nitrogen gas is bubbled for about 3 h to ensure good mixing and isotope exchange.

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Analytical Measurements in Aquatic Environments

Water sample

Biological sample

Sediment

Coprecipitation

Mineralization

Mineralization

Po Procedure 5 and 6 Sample in 8 M HNO3 Sample in 0.5 M HCl Electrodeposition of Po

Measurement by a-spectrometry

Procedure 7

Dowex 21K

Procedure 8

Sorption [Pu(NO3)6]2– Procedure 7 Pu

U After evaporation dissolution 9 M HCl

After evaporation dissolution in 9 M HCl Th

Dowex 1 ¥ 8

Sorption [UO2Cl4]2– Dowex 1 ¥ 8

After evaporation dissolution in 1 M (NH4)2SO4

Dowex 1 ¥ 8

Sorption [UO2(SO4)3]4–

Sorption [Pu2Cl6]2–

Electrolysis of Pu

Measurement by a-spectrometry

Electrolysis of U

Measurement by a-spectrometry

FIGURE 11.3

Radioanalytical determination of polonium, uranium, and plutonium.

10 mL 0.2 M KMnO4 is then added to the water sample, which is brought to pH = 9 with conc. NH4OH. Next, 10 mL 0.3 M MnCl2 is added, and nitrogen continues to be bubbled for another hour. The MnO2 is allowed to settle overnight; the overlying liquid phase is sucked off and the precipitate collected by centrifugation. The MnO2 precipitate is dissolved in 100 mL 1% H2O2 solution in 1.2 M HCl and the new solution evaporated to dryness. The dry residue is dissolved in 50 mL 8 M HNO3. 11.2.6.3 Mineralization of Suspended Matter The mineralization of suspended matter involves the decontamination of membrane filters with sediment using a mixture of hydrochloric and hydrofluoric acids, and the subsequent removal of silicon as volatile SiF4.33

Determination of Radionuclides in the Aquatic Environment

251

11.2.6.3.1 Procedure 2 Wet digestion is carried out with 0.5 mL 40% HF and 5 mL 6 M HCl in a polytetrafluoroethane (PTFE) autoclave in which the filter with the suspended matter has been placed. The autoclave is then put in a drying oven at 120°C for 2 h. After cooling, the autoclave is centrifuged and the solution evaporated to dryness on a hot plate. 1 mL 30% H2O2 and 0.5 mL 60% HClO4 are added and the mixture is heated until the H2O2 is completely decomposed. The closed PTFE vessel is then kept at 180–190°C for 2 h. After cooling and centrifuging, the HClO4 is evaporated until white fumes cease to evolve and the digestive residue is dissolved in 5 mL 8 M HNO3. 11.2.6.4 Mineralization of Sediment The method used to mineralize sediment depends on its chemical composition. In his research work, the author applied different chemical mineralization procedures to sandy, slimy, and loamy sediments.34,35 If the origin and nature of the sediment samples were unknown, procedure 3 was used. 11.2.6.4.1 Procedure 3 About 1 g of dry sediment is placed in a PTFE evaporating dish, 5 mL 30% H2O2 are added, and the mixture is slowly heated until the H2O2 has decomposed completely. Then 5 mL 65% HNO3 is added and the mixture is heated until the HNO3 has decomposed entirely. After evaporation, 5 mL 30% HCl and 5 mL 40% HF are added to the dry residue and the mixture is heated for 3 h. After evaporation, 5 mL 70% HClO4 is added to the dry residue and the solution is heated for 2 h. The perchloric acid is evaporated until white fumes cease to evolve, and the digestive residue is dissolved in 20 mL 8 M HNO3. 11.2.6.5 Mineralization of Biota 11.2.6.5.1 Procedure 4 About 1 g of dry (polonium analysis) or ashed biota (uranium and plutonium analysis) is placed in a conical flask, 10 mL 65% HNO3 is added, and the mixture is slowly warmed until the HNO3 has decomposed completely. This step is performed three times. After evaporation, the digestive residue is dissolved in 10 mL 8 M HNO3.34 11.2.6.6 Separation and Determination of Polonium 210Po and Lead 210Pb 11.2.6.6.1 Procedure 5 The aquatic samples in 8 M HNO3 are evaporated and the dry residue is dissolved in 20 mL 0.5 M HCl. After the addition of approximately 50 mg of ascorbic acid (reduction of Fe3+ to Fe2+), the solution is transferred to PTFE vessels equipped with a silver sheet bottom. Polonium is electrodeposited at 90°C for 4 h.34,36 The direct measurement of lead 210Pb activity in aquatic samples is difficult in view of the low energy of the b particles emitted. The activity of lead 210Pb is calculated indirectly by measuring the activity of polonium 210Po resulting from the decay of lead 210Pb.34,37 11.2.6.6.2 Procedure 6 After electrodeposition of 210Po, the solution is evaporated and the dry residue dissolved in 10 mL 10 M HCl. The solution is passed through a column (Ø = 10 mm; length = 100 mm) containing Dowex 1 × 8 (100–200 mesh) anion exchange resin. The remainder of the 210Po is adsorbed on the resin, whereas lead 210Pb passes through the column. The column is flushed with 40 mL 10 M HCl. The 210Pb fraction is evaporated to dryness and the residue treated with a little HNO3 to destroy any remaining organic matter. After an interval of several months, the dry residue is dissolved in 20 mL 0.5 M HCl. 209Po tracer is added and the 210Po (formed from 210Pb) is subsequently electrodeposited on a silver disc.

252

Analytical Measurements in Aquatic Environments

11.2.6.7 Separation, Purification, and Electrolysis of Plutonium The plutonium(IV) in the 8 M HNO3 + 10 M HCl solution comprises the anion complexes [Pu(NO3)6]2- and [PuCl6]2-, which are adsorbed on the anion exchange resin, whereas the Pu(III) occurs as the Pu3+ cation. Reduction of the adsorbed Pu(IV) anion complexes by ammonium iodine causes their decomposition to Pu(III).34,38 11.2.6.7.1 Procedure 7 Thirty percent H2O2 (1 mL perhydrol for each 100 mL of samples) is added to the sample solution in 8 M HNO3 and heated until the perhydrol has completely decomposed. After cooling, a “pinch” of NaNO2 is added to stabilize the Pu(IV), and the solution is passed through a column (Ø = 10 mm; length = 80 mm) containing Dowex 21 K (50–100 mesh) anion exchange resin. The column is flushed with 90 mL 8 M HNO3. The eluate is collected in a beaker and stored for uranium analysis (procedure 8). The thorium, neptunium, and americium adsorbed on the resin are eluted with 100 mL 10 M HCl, whereas Pu(IV), after reduction, is eluted with 70 mL 1 M NH4I in 10 M HCl. The eluate containing the plutonium is evaporated to dryness and the residue treated with a little aqua regia to destroy any organic matter and ammonium iodide. The dry residue is dissolved in 5 mL 10 M HCl and passed through a column (Ø = 10 mm; length = 100 mm) containing Dowex 1 × 4 (100–200 mesh) anion exchange resin in order to separate the plutonium from the thorium and uranium. The remaining thorium is eluted with 50 mL 10 M HCl, whereas the remainder of the uranium is eluted with 150 mL 8 M HNO3. After reduction, the Pu(IV) is eluted with 70 mL 1 M NH4I in 10 M HCl. The eluate is evaporated and the residue treated with a small quantity of aqua regia to destroy any organic matter and ammonium iodide. The dry residue is dissolved in 0.2 mL conc. H2SO4 and warmed for about 10 min. After cooling, 5 mL 0.01 M oxalic acid in 1 M (NH4)2SO4, two drops of 0.5 M DTPA-NH4 (the ammonium salt of diethylamine triamine pentaacetic acid), and one drop of 1% tropeolin 00 (the sodium salt 4-[(4-anilinophenyl)azo]benzenesulfonic acid) pH indicator are added. This solution is transferred to a plating cell, and NH4OH is added to bring its pH to approximately 2 (straw-yellow color). The distance between the electrodes can be adjusted by moving the platinum wire (anode) up to 5 mm. The plutonium is electroplated on a polished stainless steel disc for 2 h with a current of 1.0 A (approximately 0.63 A per 1 cm2 of cathode). Following electrolysis, 0.1 mL conc. NH4OH is added and the current switched off. The plutonium disc is removed from the plating cell and rinsed with acetone.34,39-42 11.2.6.8 Separation, Purification, and Electrolysis of Uranium Uranium U(VI) (also Fe, Co, Cu, Zn, and Cd) in 10 M HCl solution is present in the form of the complex uranyl anion UO2Cl42-, which is adsorbed on an anion exchange resin.43,44 Separation and purification of uranium from other elements is possible in sulfuric acid solution. When the H2SO4 (aq) concentration is >0.01 M, uranium exists in the anionic forms UO2(SO4)22- and UO2(SO4)34-. In contrast to uranium, other elements (Fe, Co, Cu, Zn, and Cd) do not form anionic complexes in sulfuric acid solution.34 11.2.6.8.1 Procedure 8 After evaporation, the uranium eluate (procedure 7) is dissolved in 10 mL 9 M HCl and the solution is passed through a column (Ø = 10 mm; length = 100 mm) containing Dowex 1 × 8 (100–200 mesh) anion exchange resin. The column is flushed with 60 mL 9 M HCl. The U, Fe, Co, and Cu adsorbed on the resin are eluted with 60 mL 0.5 M HNO3 and the solution is evaporated to dryness. The residue is then dissolved in 5 mL 1 M (NH4)2SO4 (pH = 1.5) and warmed for about 10 min; after cooling, the solution is passed through a column containing Dowex 1 × 8 (100–200 mesh) resin in the sulfate form. The column is flushed with 60 mL 1 M (NH4)2SO4 (pH = 1.5) solution. The uranium adsorbed on the resin is eluted with 50 mL 0.5 M HCl. The solution is evaporated to dryness and the residue treated with a little aqua regia to destroy any organic matter. The uranium fraction

253

Determination of Radionuclides in the Aquatic Environment

is dissolved in 5 mL 0.75 M (NH4)2SO4 (pH = 2) and the solution transferred to a plating cell. Uranium is electroplated on a polished stainless steel disc at a current of 1.0 A for 1.5 h. After electrolysis, approximately 0.5 mL of conc. NH4OH is added and the current switched off. On removal, the uranium disc is rinsed with acetone. 11.2.6.9 Measurement of Radionuclide Activity The activities of 210Po, 234U, 238U, 238Pu, and 239+240Pu radionuclides are measured using alpha spectrometry and a surface barrier detector with an active surface of 300–450 mm2 (ORTEC, USA) placed in a vacuum chamber connected to a 1024 multichannel analyzer (Canberra-Packard). Measuring the activity of a single preparation of polonium and uranium takes 2–4 days, and that of plutonium takes 5–10 days, depending on the activity of the sample. Figures 11.4 through 11.6 present typical spectra for the alpha measurements of polonium, uranium, and plutonium.33,34 The minimum detectable activities (MDAs) of polonium, uranium, and plutonium radionuclides are calculated from Ld MDA = _______ , tp ◊ e ◊ Y

(11.6)

where L d is the detection limit of radionuclide activity proposed by Hurtgen et al.17 (Equation 11.5), tp is the counting time (s), e—detector efficiency (usually 0.29–0.35), and Y is the recovery. The MDAs of 210Po, 238U, and 239+240Pu is between 0.10 and 0.15 mBq. 11.2.6.10 Activity Determination of Polonium, Radiolead, Uranium, and Plutonium Radionuclides The activities of 210Po, 234U, 235U, 238U, 238Pu, and 239+240Pu are calculated using Ai =

Ii ± SDi , ei ◊ Yi

(11.7)

where i is 210Po, 234U, 235U, 238U, 238Pu, or 239+240Pu; Ai is the activity (Bq); Ii is the count rate of the sample (without background) defined as the ratio Ni/tp; Ni is the 210Po, 234U, 235U, 238U, 238Pu, or

209Po

Counts

210Po

Energy

FIGURE 11.4

Alpha spectra of polonium radionuclides (209Po and 210Po).

254

Analytical Measurements in Aquatic Environments 234U

Counts

238U

232U

235U

Energy

FIGURE 11.5

Alpha spectra of uranium radionuclides (232U, 234U, 235U, and 238U).

239+240

Pu count (without background); tp is the 210Po, 234U, 235U, 238U, 238Pu, or 239+240Pu counting time [s]; ei is the detector efficiency; Yi is the recovery of 210Po, 234U, 235U, 238U, 238Pu, or 239+240Pu; and SDi is the SD of sample activity. The activity of 210Po in aquatic samples has to be calculated on the basis of the electrodeposition time of the polonium on a silver disc using Ê t ◊ ln 2 ˆ A0 = At exp Á = At exp(0.00502 ◊ t ), Ë T ˜¯

(11.8)

where A0 is the 210Po activity at the time of electrodeposition on the silver disc [Bq], At is the 210Po activity at the time of counting (Bq), t is the time interval between electrodeposition and the 210Po count (days), and T is the 210Po half-life (138.4 days). The recoveries of 210Po, 234U, 235U, 238U, 238Pu, or 239+240Pu are calculated from Yi =

Ii , ei ◊ s

(11.9)

Counts

242Pu

239+240Pu 238Pu

Energy

FIGURE 11.6

Alpha spectra of plutonium radionuclides (238Pu, 239+240Pu, and 242Pu).

255

Determination of Radionuclides in the Aquatic Environment

where Yi is the recovery; Ii is the count rate of recovery indicator (209Po, 232U, and 242Pu) defined as the ratio Nt/tp; s is the 209Po, 232U, or 242Pu activity added before radiochemical analysis (Bq); and ei is the detector efficiency. The SD for the activity of polonium (also of uranium and plutonium) is calculated from

SD =

A0 At

(I p /t p + I t /tt ) Y ◊e

,

(11.10)

where A0 is the activity of 210Po at the time of electrodeposition (Bq), At is the activity of 210Po at the time of counting (Bq), Ip is the sample count rate (with background), It is the background count rate, tp is the sample counting time (s), tt is the background counting time (s), Y is the recovery, and e is the detector efficiency. If the background count is very low, and during the analysis time A0 = At (for uranium and plutonium radionuclides), then

SD =

Np Y ◊ e ◊ tp

,

(11.11)

where Np is the number of counts of uranium (234U, 235U, and 238U) or plutonium (238Pu and 239+240Pu) radionuclides. The radiolead 210Pb activity is estimated on the basis of 210Po in growth after the lead fraction has been purified and stored for several months (up to two years) (procedure 6). The 210Pb activity at the time of sample collection is calculated from È ˘ A2 ( 210 Po) A0 ( 210 Pb) = Í ˙, ÎÍ 1 - exp ÈÎ - k (t2 - t1 ) ˘˚ ˚˙

(11.12)

where A0(210Pb) is the activity of 210Pb at the time of sample collection, A2(210Po) is the activity of Po originating from 210Pb decay following the second electrodeposition, t1 is the time interval between collection and the first 210Po count, t2 is the time interval between collection and the second 210Po count, and k is the 210Po decay constant. The uranium concentration is estimated on the basis of 238U activity from 210

1 Bq 238U = 81.6 mg U.

(11.13)

The impact of the Chernobyl plutonium fraction in the aquatic samples is calculated using the following formula33:

Fch =

Robs - Rn R - 0.04 = ch , Rch - Rn 0.56

(11.14)

where Robs is the 238Pu/239+240Pu activity ratio in the aquatic sample, Rn is the 238Pu/239+240Pu activity ratio in the global atmospheric fallout (0.04), and Rch is the 238Pu/239+240Pu activity ratio in the Chernobyl accident (0.60).

256

Analytical Measurements in Aquatic Environments

11.2.6.11 Determination of 241Pu Activity 241Pu is a low-energy beta emitter with an E 10 241Pu is the max of 21 keV and a half-life of 14.4 years. only significant beta-emitting transuranium nuclide in low-level waste from nuclear power plants. The quantitation of 241Pu in low-level waste and environmental samples is of interest because it is a precursor of other transuranium radionuclides with longer half-lives, greater environmental mobility, and greater radiotoxicity. As a beta emitter 241Pu has a relatively low radiotoxicity; however, it decays to 241Am (half-life = 432 years), which is a highly radiotoxic, alpha emitter. The two predominant sources of environmental contamination are the fallout from past nuclear weapons tests and discharges from nuclear fuel cycle operations (reprocessing, in particular) in the form of gaseous emissions or liquid effluents.45 241Pu can be determined directly by measurement in a beta proportional counting system46 and by liquid scintillation counting (samples with a relatively high content of 241Pu), and indirectly by alpha spectrometric measurements of its daughter radionuclide 241Am.47,48 Measurement based on the growth of 241Am can be carried out only after a long growth period (between 4 and 20 years). Even after four years the activity ratio 241Am/241Pu is only 1/166. The plutonium alpha spectra obtained have to be compared with the same spectra obtained 4–20 years earlier. This then enables the 241Pu content to be estimated on the basis of the increase in the 5.49 MeV peak of 241Am, which takes into account the 238Pu present in environmental samples from the Chernobyl accident. 241Pu activity is calculated from

APu = 31.3074 ◊ 0

A241 ◊ e +l

Am

Am

1 - e -l

Pu

◊t

◊t

,

(11.15)

where APu0 is the 241Pu activity at the time of sampling, A241Am is the 241Am activity measured after 4–20 years, lPu is the decay constant of 241Pu (0.050217 year -1), lAm is the decay constant of 241Am (0.001604 year -1), 31.3074 is the lPu/ lAm ratio, and t is the time from sampling to the measurement of 241Am (4–20 years).

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12

Analytical Techniques for the Determination of Inorganic Constituents Jorge Moreda-Piñeiro and Antonio Moreda-Piñeiro

CONTENTS 12.1 Introduction ...................................................................................................................... 12.1.1 Characteristics of Inorganic Constituents ............................................................. 12.1.2 Classification of Inorganic Constituents ............................................................... 12.2 Analytical Techniques ...................................................................................................... 12.2.1 Gravimetric Measurements .................................................................................. 12.2.2 Titrimetric Measurements .................................................................................... 12.2.3 Spectrophotometric Techniques Based on Molecular Absorption Radiation: Ultraviolet-Visible Spectrophotometry ............................................... 12.2.3.1 Instrumentation ...................................................................................... 12.2.4 Atomic Spectrometry ............................................................................................ 12.2.4.1 Flame Atomic Absorption Spectrometry ............................................... 12.2.4.2 Electrothermal Atomic Absorption Spectrometry ................................. 12.2.4.3 High-Resolution Continuous Source Atomic Absorption Spectrometry .......................................................... 12.2.4.4 Atomic Emission Spectrometry ............................................................. 12.2.4.5 Inductively Coupled Plasma-Optical Emission Spectrometry ............... 12.2.4.6 Atomic Fluorescence Spectrometry ....................................................... 12.2.5 Mass Spectrometric Techniques ........................................................................... 12.2.5.1 Inductively Coupled Plasma-Mass Spectrometry .................................. 12.2.6 Chemical Vapor Generation-Atomic Spectrometry (CVG-AS) ........................... 12.2.6.1 Instrumentation ...................................................................................... 12.2.7 Electrochemical Techniques ................................................................................. 12.2.7.1 Anodic Stripping Voltammetry ............................................................. 12.2.7.2 Potentiometric Sensors: ISEs and Gas-Permeable Membrane Sensors ................................................................................. 12.2.8 Separation Techniques .......................................................................................... 12.2.8.1 Ion Chromatography .............................................................................. 12.2.8.2 Capillary Electrophoresis ...................................................................... 12.2.9 Automatic Analyzers and Monitoring .................................................................. 12.3 Determination of Inorganic Constituents ......................................................................... Acronyms and Abbreviations ..................................................................................................... References ..................................................................................................................................

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12.1 12.1.1

Analytical Measurements in Aquatic Environments

INTRODUCTION CHARACTERISTICS OF INORGANIC CONSTITUENTS

Inorganic constituents are present in major, minor, and trace concentrations in aquatic environments as a result of weathering, atmospheric, and biogeochemical processes, and also as a consequence of industrial pollution. Inorganic constituents in aquatic ecosystems are a group of chemical species that are characterized by 1. A wide variety of chemical structures, from simple monoatomic ions and molecular ions to complex molecules. 2. Different roles in aquatic ecosystems, from acting as nutrients for living organisms (nitrogen and phosphorus compounds) to exerting toxic effects on such organisms (arsenic and mercury). 3. A variety of aggregations, for example, dissolved inorganic constituents coexisting with different dissolved gases such as O2, NO2, or CO2, or inorganic constituents (such as phosphorus compounds and metals) are bonded to particulate matter suspended in water—the latter is more common. 4. A wide range of concentrations ranging from ultratrace levels of around ng L -1 (some heavy metals in sea water) to concentrations in the mg L -1 and % (m/v) ranges (major ions and nutrients). In the absence of any human impact, the relative proportions and rates of dissolution of substances in natural waters are highly variable, depending on the local geological, climatic, and geographical 2+ conditions. Ions such as Cl- and Na + (and, to a lesser extent, SO 24 and Mg ) are the major components of sea water. The major constituents of world river waters are Ca2+ and HCO 3- (from weather+ 2+ 2+ ing of CaCO3). In river waters, several ratios of SO 24 , HCO 3 , K , Mg , and Ca to Cl are usually greater than those in sea water.1 Since ground water often occurs in association with geological materials containing soluble minerals, higher concentrations of dissolved salts are normally expected in ground water than in surface water. Ground water usually contains high concentrations of ions -1 2 such as Ca2+, HCO 3-, Na +, Mg2+, SO 24 , and Cl (from 1 to 1000 mg L ), and some toxic elements (As and Se). In general, trace elements such as As, Ba, Cd, Cr, Co, Cu, Mn, Ni, Pb, Sr, and Zn are present at lower concentrations in sea water than in surface water. This is what justifies the use of analytical techniques of very different sensitivities, which enable ions and dissolved gases to be determined at very different concentration levels.

12.1.2

CLASSIFICATION OF INORGANIC CONSTITUENTS

The inorganic constituents of aquatic ecosystems can be classified as follows: 1. Nutrients—these are elements essential to the metabolism of living organisms. Nitrogen, phosphorus, and silicon are the most important and commonly studied nutrients in aquatic ecosystems. a. Nitrogen compounds are essential for living organisms as they are important constituents of proteins. In the aquatic environment, inorganic nitrogen occurs in a range of oxidation states: nitrate (NO3-), nitrite (NO2-), the ammonium ion (NH+4), and molecular nitrogen (N2). b. Phosphorus compounds occur in aquatic systems in both particulate and dissolved species. The speciation of different phosphate compounds (PO43-, H2PO4-, and HPO42-) in water depends on the ambient pH. Artificial increases in phosphate concentrations as a result of human activities are the main cause of eutrophication of rivers and lakes.

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c. Silicon is also an essential element for aquatic plants such as diatoms. Si is present in water in dissolved (silicic acid), suspended, and colloidal forms. 2. Trace elements—elements such as Al, As, Be, Cd, Cr, Cu, Fe, Hg, Mn, Mo, Ni, Pb, Sb, Se, Tl, V, and Zn are present in the aquatic environment as a result of the weathering of rocks and soils (surface and ground waters) and of industrial waste water discharges and mining activities. The toxicity of trace elements in water depends on their concentration and oxidation state (Cr or As). 3. Major ions and inorganic nonmetallic substances—these constitute a heterogeneous group of species including major ions, halides, cyanide, and sulfur species (Na +, K+, Ca2+, Mg2+, 2CO32-, HCO 3-, Cl-, F-, SO 24 , SO 3 , S , and CN ) as well as dissolved gases (O2, N2, CO2, and NO2). a. Major ions, halides, cyanide, and sulfur species: sodium (Na +) and chloride (Cl-) are two of the most abundant constituents of natural fresh and sea water. Aquatic environments contain high concentrations of Na + and Cl- and also Ca2+, Mg+, CO32-, F-, SO 24 , SO 3-, and S2-. This is because their salts are extremely soluble in water and are readily dissolved from rocks and minerals (sedimentary rocks, fluorapatite, gypsum, pyrite, etc.) as a result of weathering and surface runoff. Ions such as Ca2+, Mg+, CO32-, and HCO 3- are responsible for the hardness and alkalinity of water. K+ and CN- are found in low concentrations in natural waters since potassium-containing rocks are relatively resistant to weathering, and cyanide is present in the environment as a result of industrial discharges. Certain chlorine compounds (hypochlorite and chloramines) are present as a consequence of the chlorination of drinking water and waste water treatment. b. Dissolved gases such as O2 and N2 are the major dissolved gases in natural waters; inorganic carbon, in the form of dissolved CO2, together with N2O and Cl2 from the disinfection of drinking and waste waters are also present in trace concentrations.

12.2

ANALYTICAL TECHNIQUES

In view of the wide variety and concentrations of inorganic constituents in aquatic environments, there are a great number of analytical techniques used to determine these compounds. They include 1. Gravimetric measurements for silica and sulfate. 2. Titrimetric measurements: alkalinity titration for carbonate and bicarbonate ion determinations, argentometric and potentiometric titrations for determining chloride, and iodometric titration for sulfite, chlorine, and dissolved oxygen. 3. Spectrophotometric techniques based on molecular absorption radiation for determining nutrients (NO 3-, NO 2-, NH +4 , N2, phosphorus, and silicon) as well as chlorine, fluoride, cyanide, sulfate, and sulfide. 4. Spectrophotometric techniques based on the dispersion of radiation, for example, the nephelometric determination of sulfate. 5. Spectrometric techniques based on atomic absorption or the emission of radiation: flame atomic absorption spectrometry (FAAS), electrothermal atomic absorption spectrometry (ETAAS), inductively coupled plasma-optical emission spectrometry (ICP-OES), inductively coupled plasma-mass spectrometry (ICP-MS), and cold vapor (CV)/hydride generation (HG), mainly for trace and ultratrace metal determinations. 6. Electrochemical techniques: anodic stripping voltammetry (ASV) and cathodic stripping voltammetry (CSV) for determining trace elements, and potentiometric sensors for determining dissolved gases (CO2, NO2, SO2, NH3, H2S, HCN, and HF) as well as chloride, fluoride, cyanide, and sulfide. 7. Separation techniques such as ion chromatography (IC) and capillary electrophoresis (CE) for determining major and minor ions.

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12.2.1

GRAVIMETRIC MEASUREMENTS

Gravimetric methods are based on the quantitative measurement of an analyte by weighing a pure and insoluble compound from the analyte. Analytical balances, which provide accurate and precise data, are used for this purpose. Detailed information on gravimetric methods and their applications can be found in the literature.3 In summary, a typical gravimetric procedure to determine an unknown concentration of an analyte in solution is as follows: 1. Quantitative and selective precipitation of the analyte from solution, for example, Ag+ (aq) + Cl- (aq) Æ AgCl(s); Ca2+ (aq) + C2O42- (aq) Æ CaC2O4(s); Ba2+ (aq) + SO 24 (aq) Æ BaSO4(s).

2.

3.

4. 5.

The composition of the insoluble compound (precipitate) obtained from the analyte must be known and stable. Poorly soluble substances may form colloidal suspensions (particle diameters from 10-7 to 10-4 cm). The formation of a colloidal suspension can be minimized or prevented by carrying out the precipitation from a dilute solution of the analyte, at a temperature close to the boiling point of water and with constant stirring. The relative supersaturation affects the particle size and is expressed as Q - S/S, where Q is the instantaneous concentration of the added species and S is the equilibrium solubility of the compound that precipitates. Particle size seems to be inversely proportional to relative supersaturation. The electric double layer formed during precipitation keeps the colloidal precipitate particles from coming into contact with each other, thus preventing further coagulation. There are two ways of bringing the particles closer together and of increasing the probability of coagulation: (a) Heating increases overall thermal motion, affecting the mobility of adsorbed ions and colloidal precipitate particles. The final effect is that there are collisions of particles, which cause the particle size to increase as a result of coagulation. (b) Increasing the electrolyte concentration in the solution leads to a decrease in the mean radius of the electric double layer and encourages further coagulation. A procedure known as high-temperature precipitate digestion is usually carried out to enhance coagulation, and hence increase the particle size of the precipitate. It must be mentioned that other processes such as peptization, surface adsorption, mixed crystal formation, occlusion, and mechanical entrapment can occur during the precipitation procedure, causing the results to be positively or negatively erroneous. Isolation of the precipitate by filtering and rinsing. Having been isolated, the precipitate must be thoroughly rinsed in order to remove contaminants; great care must be taken to ensure that no precipitate is lost during either filtration or rinsing. Drying the solid in an oven to remove the solvent: the precipitate must be heated (at different temperatures) until a stable, dry state is reached. Reliable results are founded on a thorough knowledge of the precipitate’s properties. Weighing of the solid on an analytical balance. Calculation of the analyte concentration in the original solution from the weight of the precipitate.

12.2.2 TITRIMETRIC MEASUREMENTS Titrations represent a comprehensive set of procedures useful for performing quantitative determinations in analytical chemistry. Detailed information on titrimetric methods and their applications can be found in the literature.4

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Titration involves measuring the volume of a standardized solution containing a known concentration of a reagent (titrant) that reacts quantitatively with the analyte. Titrations can be done by adding the standardized solution from a burette to a sample solution until the reaction between the titrant and the analyte is complete. The volume of the titrant used to carry out the titration is determined by the difference between the initial and final readings of the burette. The equivalence point of a titration is reached when the amount of titrant is chemically equivalent to the amount of analyte in the sample; at this point, the number of gram equivalents of titrant and analyte are equal. However, the equivalence point is a theoretical point that cannot be determined experimentally. We can only estimate this point by observing any physical change that accompanies the equivalence condition. We must ensure that the difference between the equivalence point volume and the end point volume is minimal; this difference is known as the titration error. Sometimes, an indicator is added to the sample solution in order to elicit an observable physical change (end point) at or near the equivalence point. Typical changes of an indicator are the appearance or disappearance of color, color changes, and the appearance or disappearance of turbidity. Instruments are commonly used to detect end points; they respond to a certain property of the solution (e.g., pH for potentiometric titrations; conductivity, conductometric titrations; and radiation absorption, photometric titrations) that typically changes during the titration. End point detection by instrumental methods provides, among other benefits, greater accuracy and precision, because the error inherent in the visual observance of indicator change is avoided. In addition, these end point detection methods are more appropriate for samples where turbidity or color is involved. Potentiometric titrations are useful when a change in potential occurs during titration. Thus, acid–base titrations can be monitored with a pH meter, precipitation, and complexometric titrations with ion-selective electrodes (ISEs). The equivalence point is determined mathematically: it is the point of inflection on a plot of potential versus the volume of titrant added. The equivalence point can be better visualized if the first or second derivative (DE/DV or D2E/D2V, respectively) is plotted against the volume of titrant added.

12.2.3 SPECTROPHOTOMETRIC TECHNIQUES BASED ON MOLECULAR ABSORPTION RADIATION: ULTRAVIOLET-VISIBLE SPECTROPHOTOMETRY Spectrophotometry is based on the simple relationship between the molecular absorption of ultraviolet-visible (UV-VIS) radiation by a solution and the concentration of a colored species in such a solution. For these groups of techniques involving matter-radiation interaction, electromagnetic radiation should be regarded as a stream of discrete packets behaving as individual particles called photons. The energy of a photon is proportional to the frequency of the radiation and is given by the Planck equation: E = hn = hc/l. Detailed information on UV-VIS spectrophotometry can be found in the monographs by Heinz-Helmut5 and Harris and Bashford.6 The absorption of radiation is the process by which a chemical species selectively attenuates (or selectively decreases the intensity of) certain frequencies of electromagnetic radiation. According to quantum theory, each particle (atom, ion, and molecule) has a unique set of energy states. At room temperature, most particles are in the ground state. When a photon interacts with a particle, it is likely to be absorbed if its energy matches any of the energy jumps quantified for this particle. Under these conditions, the energy of the photon is transferred to the particle, whose valence electrons are promoted to a higher energy state, called an excited state (M + hn Æ M*). After a short time (10-6 to 10-9 s), the excited species relaxes to the ground state; during this process the excess energy is transferred to adjacent particles. Relaxation is manifested by the photochemical decomposition of the excited species (M*) and the formation of a new species, or by the re-emission of the energy in the form of fluorescent or phosphorescent radiation. The absorption characteristics of a species can be described by an absorption spectrum showing the beam radiation attenuation versus the wavelength, frequency, or wave number. Each line is attributed to the transition of electrons from one of the many states of vibrational and rotational energy associated with ground state to the

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excited electronic state. Because of the large number of possible vibrational and rotational states, their energies differ little among themselves, and therefore the number of lines contained in a typical band is very high. Molecular spectrophotometry makes use of the transitions located in the ultraviolet (UV) (10–400 nm), visible (VIS) (400–1000 nm), and infrared (IR) (0.78–1000 μm) regions of the electromagnetic spectrum. Two important terms are used in absorption spectrophotometry. One is the transmittance T, defined as the ratio (%) of the intensity of the radiation beam emerging from the solution I to that of the incident beam I0 : T = I/I0. The other is the absorbance, A, defined as the negative logarithm of the transmittance T : A = -log10 T = log I0/I. Unlike the transmittance, the absorbance of a solution increases with increasing beam attenuation. The functional relationship between the analytical signal measurement (absorbance) and the analytical parameter of interest (concentration) is known as the Bouguer–Lambert–Beer law and is expressed as A = log (I0/I) = abc, where A is the absorbance of the solution, a is the proportionality constant called the absorptivity, b is the radiation path length within a sample, and c is the concentration of the solution. When the concentration is expressed in mol L -1, absorptivity is represented by e and is called the molar absorptivity. This linear relationship is a generalization, however, as there are deviations from the direct proportionality between absorbance and concentration for a fixed path length. Some of these deviations are technical deviations from the law when concentrations higher than 0.01 M are measured. Others are consequences of the experimental measurements, for example, the use of polychromatic and dispersive radiation (instrumental deviations), or they may derive from analyte association or dissociation with the solvent or chemical changes to give products with different absorption properties (chemical deviations). Because the sample must be placed in a cell (sample container), there is an interaction between the radiation and the cell walls, which produces a loss of power at each interface as a result of reflections and absorptions. In order to prevent or minimize these effects, the power of the transmitted beam is usually compared with the same radiation beam that passes through a reference cell containing only the solvent. Therefore, the measured absorbance is defined by the equation: A = log (Isolvent/Isample) = log (I0/I), where Isolvent and Isample are the intensities of the beams emerging from the solvent and sample cell, respectively. 12.2.3.1 Instrumentation Instruments used for transmittance or absorbance measurements consist of five basic elements: 1. A light source—a tungsten filament; hydrogen, mercury, or deuterium lamps; a xenon discharge lamp—that provides an intense, stable, and constant radiation. 2. A wavelength selector—interference and absorption filters or a monochromator (prisms and diffraction gratings)—to isolate the desired emission line. 3. A sample cell—normally parallelepiped in shape with a standard length of 1 cm and made of glass for the VIS region or quartz (or fused silica) for the UV region. The cell has an opening for inserting the sample and a stopper to prevent evaporation. 4. A detector—phototubes, photomultiplier tubes, photovoltaic cells, or photodiodes, which convert radiant energy into a measurable signal. 5. A data processing unit—an electronic device that amplifies, filters, and performs mathematical processes on the signal. These components are assembled in different ways to produce several instrument designs. Here we consider two general types of spectroscopic instruments: 1. The photometer: A simple instrument that uses absorption or interference filters for wavelength isolation and a photoelectric device to measure the radiant power. 2. The spectrophotometer: A specialized device capable of recording the various components of complex radiation.

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These instruments exist in three configurations: 1. Single-beam instruments: These consist of a radiation source, a monochromator, and two cells for the reference and the sample solutions, which are alternately inserted in the light path; also a detector, an amplifier, and a reading device. These instruments require a stable voltage source to prevent errors arising from variations in the beam intensity. Also, differences between cells (mainly irregularities in the walls) are not easily compensated for. 2. Dual-beam instruments: In these the incident light beam is split by a rotating mirror-chopper into two separate beams, one of which passes through the sample and the other passes through the reference. The alternating beams reaching the detector thus permit a simple mathematical treatment of signals (signal modulation). This design is routinely used and leads to good results, since it minimizes drift of the radiation source and the amplifier. 3. Multichannel instruments: These are equipped with a photodiode array detection system. The radiation from a tungsten or deuterium lamp is focused on the sample or solvent cell, and then passes to a diffracting grating. The scattered radiation arrives at the diode array, which simultaneously detects and analyzes various wavelengths. Specific applications of spectrophotometry are turbidimetry and nephelometry; both techniques are based on the dispersion of radiation from particles containing the target analyte. Measurement of the incident beam attenuation due to the presence of particles is the basis of the turbidimetry approach. In contrast, measurement of the light scattered (dispersed) by such particles at 90° to the incident beam is the basis of nephelometry. The amount of dispersed radiation depends on the density, size, shape, and refractive index of such particles. The effects of all these factors are covered by the Rayleigh law, which establishes the amount of radiation reflected toward the detector. They also depend on the wavelength: I/I0 = K(Nv2/l4) sin a2, where I and I0 are the respective intensities of the dispersed and incident beams, a is the angle measured relative to the excitation light, N is the number of particles of volume v, and l is the wavelength of the light.

12.2.4

ATOMIC SPECTROMETRY

Atomic spectrometry techniques make use of the absorption or emission of radiation (optical emission or fluorescence emission) by atoms or ions. Therefore, the physicochemical principles underlying this huge group of techniques (based on the interaction between electromagnetic radiation and matter) are similar to those of UV-VIS or IR absorption spectrometry for molecules. However, there is an important difference between atomic spectrometry and molecular spectrometry: in the former the sample must first be atomized. In fact, the ways in which elemental atoms or ions (atomization) are obtained constitute the foundations of the various atomic spectrometry techniques in use. The atomization mechanisms in atomic spectrometry can be split into two main groups: thermal atomization (atomization by heating at very high temperatures) and chemical atomization (atomization through a chemical reaction that converts the aqueous analyte into an atomic vapor). Flames (temperatures from 1700°C to 3100°C) and plasmas (temperatures ranging between 4000°C and 6000°C) are very efficient means of atomization; they are used in FAAS, flame atomic emission spectrometry (FAES), ICP-OES, and ICP-MS. High temperatures (up to 3000°C) can also be obtained if an intense electrical current is set up between two electrical contacts. This type of atomization by electrical heating (electrothermal atomization) is the basis of ETAAS. For some elements such as Hg, atoms (atomic vapor) can also be obtained by chemical reaction. The ions in solution (Hg2+) can be efficiently reduced to Hg, which is a vapor at room temperature. Similarly, other elements with high electronegativities (i.e., electronegativities close to that of hydrogen) can be efficiently converted into vapors by a reduction reaction similar to that used for mercury. This is done with the so-called covalent hydride-forming elements (As, Bi, Pb, Sb, Se, Sn, and Te), which are converted into gaseous hydrides at room temperature. These hydrides are then heated

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(electrically in most cases) and decomposed into an atomic vapor. In general, both CV and HG are included in a more global concept—chemical vapor generation (CVG)—which embraces not only classical reduction reactions but also other reactions that generate volatile compounds. Following CVG, measurements are mostly carried out by ICP-OES (cold vapor-inductively coupled plasmaoptical emission spectrometry, CV-ICP-OES; hydride generation-inductively coupled plasmaoptical emission spectrometry, HG-ICP-OES; or chemical vapor generation-inductively coupled plasma-optical emission spectrometry, CVG-ICP-OES), but also by atomic absorption spectrometry (AAS) (cold vapor-atomic absorption spectrometry, CV-AAS; hydride generation-atomic absorption spectrometry, HG-AAS; or chemical vapor generation-atomic absorption spectrometry, CVG-AAS), atomic fluorescence spectrometry (AFS) (cold vapor-atomic fluorescence spectrometry, CV-AFS; hydride generation-atomic fluorescence spectrometry, HG-AFS; or chemical vapor generation-atomic fluorescence spectrometry, CVG-AFS), atomic emission spectrometry (AES), or ICP-MS (cold vapor-inductively coupled plasma-mass spectrometry, CV-ICP-MS; hydride generation-inductively coupled plasma-mass spectrometry; HG-ICP-MS; or chemical vapor generation-inductively coupled plasma-mass spectrometry, CVG-ICP-MS). Atomization sources can also be classified according to the technique of introducing the sample into the atomizer. Sample introduction is continuous when the sample is aspirated during fixed flow and noncontinuous when a discrete volume of sample is introduced into the atomizer. The first system (flame- and plasma-based atomizers) supplies a constant atomic signal; in the second one (electrothermal atomizers) the atomic signal reaches a maximum value and then drops to zero. 12.2.4.1 Flame Atomic Absorption Spectrometry Because of its inherent simplicity and low capital cost, FAAS is one of the most commonly used atomic techniques in the analytical laboratory for the determination of inorganic compounds in waters. A more detailed description of FAAS instrumentation will be found elsewhere.7 12.2.4.1.1 Instrumentation 12.2.4.1.1.1 Source of Radiation The radiation source for FAAS instrumentation is quite similar to that of other AAS techniques, such as ETAAS or CVG-AAS (CV-AAS and HG-AAS). The one most commonly applied is the line source (LS), which generates a characteristic narrowline emission of a selected element. There are two principal LSs for AAS: the hollow cathode lamp (HCL) and the electrodeless discharge lamp (EDL).8 An HCL consists of a tungsten rod (anode) and a hollow cylindrical cathode lined with the target element. Both electrodes are contained within a glass envelope filled with an inert gas (Ar or Ne) at low pressures (1–5 Torr). The characteristic radiation is obtained when a potential of approximately 300–500 V is applied between the two electrodes, which causes the inert gas contained in the lamp to ionize, and the ions (cations) and electrons to migrate to the cathode and anode, respectively. On application of a high voltage, the bombardment of the cations on the inner surface of the cathode causes metal atoms to sputter out of the cathode cup, producing an atomic vapor. Further collisions excite these metal atoms, which, on returning to the ground state, produce an intense and characteristic radiation. A typical EDL consists of a hermetically sealed quartz envelope containing an inert gas (Ar) at very low pressure and the element or salt of the target element. In order to ionize the inert gas, microwave radiation (approximately 100 MHz) or, as is usually the case, radio frequency (RF) radiation (from 100 kHz to 100 MHz) is applied. Commercially available RF EDLs have a built-in starter, run at 27 MHz, which provides a high voltage spark to ionize the filler gas to initiate the discharge. Although most of the radiation sources for AAS are LSs, the great advances in detector technology, especially the development of solid-state array detectors and charge-coupled devices (CCDs), have led to the successful application of continuous sources (CSs) for AAS. A modern CS is based on a conventional xenon short-arc lamp that has been optimized to run in the so-called hot-spot mode.9 This discharge mode requires the appearance of a small plasma spot close to the cathode

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surface. In order to obtain this plasma, new CSs have a short interelectrode distance and operate at high xenon pressure. In the same way, new materials and geometries for both anode and cathode rods have been carefully optimized. 12.2.4.1.1.2 Flame Atomizer The energy supplied by a flame for AAS is used both to atomize the sample and to maintain the atomic vapor within the light path of the spectrometer. In this sense the flame acts as an atomization cell in which the atoms interact with the radiation from the lamp or in which the excited atoms deactivate by emitting the characteristic radiation. The premixed laminar flame, in which the fuel and the oxidant gases are mixed in an expansion chamber prior to entering the burner, is the most commonly used atomization cell.7,8 There are two different flames depending on the nature of the oxidant gas: the air–acetylene flame and the nitrous oxide–acetylene flame. The air–acetylene flame (with a slot length of 100 mm) is the one most commonly used and reaches temperatures from 2000°C to 2500°C. But such temperatures are insufficient for atomizing refractory elements or those forming thermally stable oxides or carbides. In such cases, the nitrous oxide–acetylene flame (with a slot length of 50 mm), which attains temperatures of approximately 3000°C, is preferred. 12.2.4.1.1.3 Nebulizers The liquid sample is introduced into the flame as a fine aerosol, which is generated by a nebulizer/expansion chamber arrangement. Pneumatic nebulizers, especially the pneumatic concentric nebulizer, are the most widely used in FAAS instruments. Once the aerosol is generated, it passes through the expansion (spray) chamber, where large droplets collect on its walls and drain away. A number of baffles are placed in the spray chamber to ensure that only the smallest droplets reach the flame. The efficiency of aerosol generation with the combination of a pneumatic nebulizer and an expansion chamber is around 10–15%; but the sensitivity of this arrangement is poor. In order to obtain a more concentrated aerosol, an impact bead may be placed in the path of the initial aerosol inside the spray chamber.8 The primary aerosol generated by the nebulizer impacts on the bead and secondary fragmentation takes place; this increases the number of fine drops that can reach the flame and improves the efficiency of nebulization. The impact bead is normally made of glass, but there are other designs based on ceramics. The development of new, highly efficient nebulizers, described in detail in the section on ICPOES (Section 12.2.4.4.1), has meant that a more concentrated aerosol and a more sensitive FAAS determination is achievable. Similarly, the use of slotted tube atom traps (STATs) and water-cooled atom traps (WCAT)10,11—the latter have undergone modification in recent years12—enhances sensitivity with regard to volatile elements like Cd and Pb because of the long residence time of these atoms in the tube. 12.2.4.1.1.4 Background Correction Analyte absorption can be affected by background absorption. Possibly nonspecific, this latter type of absorption is attributed to light scattering on particulates formed by recombination of the sample matrix at cold spots. Background absorption can also be a broad molecular absorption signal caused by radicals or molecules vaporized in the atomizer. Therefore, in order to obtain the net absorbance of the analyte atoms, the incident radiation scattered or absorbed must be subtracted from the total measured absorbance. This operation is known as background correction, and there are different ways of carrying it out. The background correction system usually used is based on the nonspecific continuous radiation emitted by an additional source; for example, a deuterium arc lamp or a hydrogen arc lamp for correction below 400 nm, or a tungsten halogen lamp for the VIS region.7 The level of atomic absorption due to the deuterium lamp is negligible, but the level of nonspecific absorption is the same. Therefore, the signal recorded with the LSs can be subtracted from that recorded with the CS, and the background absorption can be removed. This method for background correction is inexpensive, but background signals larger than 0.5 units cannot be compensated for. In addition, there are other drawbacks associated with the relatively high noise and overcorrection, which occurs when

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emission lines from other elements in the sample lie close to the characteristic emission line of the target element. Other background correction systems include the Zeeman effect and the Smith–Hieftje background correction. A detailed description of the operational principles of these methods is beyond the scope of this chapter and the required information can be found in the relevant literature.7,13 The advantages of these methods over deuterium lamps are that high background signals (up to 2.0 units) and structured backgrounds can easily be corrected for. 12.2.4.2 Electrothermal Atomic Absorption Spectrometry The atomic absorption spectrometer for ETAAS is the same as that used for FAAS/FAES except that a graphite furnace atomizer replaces the flame/burner arrangement in the light path of the spectrometer. The graphite furnace consists of a graphite tube with graphite electrodes clamped at either end and held axially in line with the light source. The furnace is heated by a low voltage (10 V) and high current (up to 500 A) via water-cooled contacts at each end and the whole atomizer is purged with an inert gas (Ar or N2). 12.2.4.2.1 Instrumentation 12.2.4.2.1.1 Atomizer Sample introduction in ETAAS is discrete, with small volumes of between 5 and 100 μL being placed on the inner surface of a graphite tube through a small opening, often with the aid of an autosampler. The discrete volume can also be deposited directly on to the inner walls of the tube (wall atomization) or on to a small platform (L’vov platform) located within the graphite tube (platform atomization). A conventional graphite tube for longitudinal heating consists of cylinders 3–5 cm in length and 3–8 mm in diameter. As the electrical current is applied at the ends of the tube, there is a temperature gradient along the graphite tube: the central portion is several hundred degrees hotter than the ends (nonisothermal conditions). This can lead to condensation of the analyte or recombination with other species at the cooler ends of the tube. As L’vov himself suggested, the sample can be deposited on a small graphite platform (L’vov platform) only loosely connected to the tube walls.14 Thus, although the graphite tube is directly heated by the electric current, the platform is heated by radiation and convection from the tube walls. There is therefore a time lag between the heating of the tube and that of the platform, and atomization occurs only when the surrounding gas is relatively hot and the whole operation is taking place isothermally. In addition to the L’vov platform technology, the tube in some modern instruments is heated transversely, that is, from the sides. These atomizers are commonly known as transversal heated graphite atomizers (THGAs). This heating method prevents a temperature gradient from occurring along the tube and offers other advantages over longitudinal heating, such as more efficient atomization, less tailing of the absorption signal, and a decrease in the memory effect. The use of isothermal operation (L’vov platform and/or transversal heating) is one of the characteristics of the stabilized temperature platform furnace (STPF) concept, which is the basis of most ETAAS applications.15 These recommendations include (1) isothermal operation; (2) the use of a matrix modifier; (3) measurement of an integrated absorbance signal rather than peak height; (4) rapid heating during atomization (maximum power heating); (5) fast electronics to follow the transient signal; and (6) the use of the Zeeman effect background correction system. Apart from atomization in the isothermal operation mode, there is another characteristic derived from the STPF concept that is worth commenting on, namely, matrix modification. 12.2.4.2.1.2 Matrix Modification Matrix modification, also called chemical modification,16 can be defined as a process aiming to separate the analyte from the matrix, therefore facilitating interference-free determinations. This process consists of the addition of a reagent (modifier) or a combination of reagents, which react with the analyte or with the matrix, thus permitting selective volatilization and, consequently, the separation of analyte from the matrix at some point of the graphite furnace temperature program. A matrix or chemical modifier acts in two main ways. Firstly,

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it removes concomitants (matrix) by reducing matrix volatility. In this case, the chemical modifier reacts with the matrix and the product of this reaction is more volatile, so it may be lost at low temperatures (i.e., during the charring step). Classical examples of this behavior are exhibited by compounds such as ammonium nitrate and nitric acid, which volatilize chloride ions by forming volatile ammonium chloride, or by gas matrix modifiers such as oxygen or synthetic air, which are used to combust a sample with a high organic matrix content. The second mode of action of a modifier is direct reaction with the analyte to convert it into a phase with greater thermal stability, that is, to reduce analyte volatility. In this way, the charring stage can be carried out at higher temperatures, allowing a more efficient removal of the matrix but without the loss of analyte. Examples of this type of matrix modifier include transition metal ions (mainly Pd), which form thermally stable intermetallic compounds with analytes, and magnesium nitrate, which thermally decomposes to magnesium oxide, and in the process traps analyte atoms in its crystalline matrix; it is thermally stable until 1100°C. In fact, the most frequently reported mixture for matrix modification consists of Pd(NO3)2 and Mg(NO3)2, proposed by Schlemmer and Welz as a universal chemical modifier.17 Some chemical modifiers behave in other ways—they decrease analyte volatility or concomitant volatility—so that concomitants (matrix) are volatilized during the cleaning step. Examples of the first behavior are certain organic acids, such as ascorbic or citric acids, which react with volatile elements, thereby diminishing their volatilities. An example of the second type of behavior is the use of ammonium molybdate, which reacts with phosphate ions to form the highly refractory ammonium molybdophosphate. The use of organic reducing agents in combination with Pd has extended the usefulness of Pd as a chemical modifier for volatile elements.18 The formation of thermally stable intermetallic compounds with Pd is temperature-dependent and occurs at temperatures close to 1000°C. At these temperatures volatile elements may be lost before Pd can react with them. The combination of Pd and a reducing agent guarantees the reduction of Pd at an early stage of the temperature program; for determining volatile elements this mixture is extremely convenient.18 Finally, the use of permanent chemical modifiers must be mentioned. Such chemical modification involves coating the graphite tube with a noble metal such as Ir, Pt, W, or Zr. These modifiers behave in much the same way as aqueous Pd in that thermally stable intermetallic compounds are formed on the hot inner surfaces of the coated graphite tube. 12.2.4.3 High-Resolution Continuous Source Atomic Absorption Spectrometry New developments in solid-state array detectors and CCDs, as well as powerful, specially designed echelle spectrometers and improvements in CSs, have led to a fresh concept for AAS, which allows the simultaneous determination of several elements based on atomic absorption measurements.9 12.2.4.3.1 Instrumentation There is a commercially available instrument for HR-CS AAS in which a flame, a graphite furnace, or a CVG system are used to carry out atomization. The instrument has a double monochromator with a prism premonochromator and a high-resolution echelle monochromator, which allows a wavelength from 189 to 900 nm to be used in a sequential measurement mode.19 The echelle monochromator and the prism are arranged in similar Littrow mountings coupled with two small folding mirrors. The double-pass mode in the Littrow prism increases the angular dispersion for minimum prism size and the autocollimation mode of the 76° echelle grating results in maximum dispersion and resolving power. The radiation from the CS is focused through the atomizer on to the spectrometer entrance slit with the aid of two elliptical mirrors. The collimated beam having been refracted by the prism, a small segment of the low-dispersed continuum spectrum passes through the entrance slit of the high-resolution echelle monochromator. The rotation of the prism ensures that the selected spectral interval, within the analytical line of interest and its neighborhood, is transmitted.

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A detector for HR-CS AAS must have a large dynamic range, which means that most of the application area of the detector must be free of shot-noise. This parameter is calculated by the ratio between the saturation capacity and the square of the readout noise. Detectors with large dynamic ranges are needed because analyte measurements as well as background absorption arrive at the detector simultaneously. CCDs are therefore the most favored CS AAS detectors because of their saturation capacities between 600,000 and 800,000 electrons per pixel and readout noises of 5–30 electrons. This leads to a shot-noise-limited dynamic range of 600–800, the results of which are adequate for AAS requirements. The CCD in commercially available instruments has 576 pixels, which make it possible to make highly resolved and truly simultaneous observations of a spectral range of almost 1 nm. 12.2.4.4 Atomic Emission Spectrometry When samples are atomized at very high temperatures, a significant proportion of atoms or ions may be excited by the absorption of thermal energy. On returning to the ground state, these atoms or ions emit radiation of the element-characteristic wavelength, the intensity of such emission being proportional to the concentration of atoms. Although many types of excitation sources are available, flames and plasmas are nowadays the most important ones for AES; they are the basis of FAES and (ICP-OES). Formally, the instrumentation for FAES is similar to that for FAAS, except for the external radiation source, which is not required. The instrumentation for ICP will be discussed in the following section. 12.2.4.5 Inductively Coupled Plasma-Optical Emission Spectrometry Because of its versatility and productivity, ICP-OES is one of the most useful techniques in instrumental element analysis. The multielement determination capacity of this technique enables it to deal with the basic workload in many routine laboratories. Complete information on all aspects relating to ICP-OES can be found in a few monographs.20-22 12.2.4.5.1 Instrumentation The basis of ICP is plasma, a very hot ionized gas, sometimes referred to as the fourth state of aggregation. This energetic plasma is sustained in a quartz torch placed in a RF oscillating magnetic field. The very high temperature in the plasma causes the complete breakdown of the sample, and the atoms and ions are excited to emit their characteristic radiations. Argon is usually chosen as the plasma gas because of its inertness, optical transparency to the UV-VIS spectrum, moderately low thermal conductivity, and high first ionization energy.8 12.2.4.5.1.1 Plasma Torch The torch consists of three concentric cylinders: the outer tube is the channel for the coolant gas (outer, coolant, or plasma gas), the intermediate one is the channel for the auxiliary gas, and the inner one the channel for the sample carrier gas (nebulizer gas). The plasma gas flows tangentially into the torch along the outer tube until shortly before it reaches the plasma. The gas cools the torch but also maintains the plasma; flow rates between 10 and 20 L min-1 are typical. The intermediate tube is approximately 16 mm in diameter and serves to force the coolant gas to flow tangentially along the outer tube; it also enables another gas (the auxiliary gas) to be introduced. Typical auxiliary gas flow rates are between 0 and 2 L min-1. After nebulization, the sample is introduced as an aerosol through the inner tube, also called the injector. This tube is usually made of quartz or aluminum oxide. Nebulizer flows are normally low (from 0.6 to 1.0 L min-1). Modern ICP-OES instruments allow both radial and axial viewing (the dual view concept); in them, the plasma lies horizontally and the optics is set up for axial viewing. 12.2.4.5.1.2 RF Generators In order to ignite the plasma a high frequency electrical field is applied. Two types of designs for RF generators can be used: crystal-controlled and free-running generators. In the former, an oscillator circuit incorporating a crystal oscillating at a fixed frequency

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is responsible for inducing the electrical field. In the latter, changes in power loading are compensated by slight shifts in the frequency of the oscillation circuit in order to bring the whole circuit back into resonance. 12.2.4.5.1.3 Nebulizers and Spray Chambers The nebulizer converts the sample liquid into an aerosol. Unlike FAAS/FAES, where solution uptake is by free aspiration, the solution to be nebulized in ICP is usually moved by a peristaltic pump. There are three different types of nebulizers: pneumatic nebulizers, glass frit (fritted disc) nebulizers, and ultrasonic nebulizers.23 The pneumatic concentric nebulizer, commonly used in FAAS/ FAES, and the cross-flow and Babington nebulizers are the most commonly reported pneumatic nebulizers in ICP-OES. Low-flow nebulizers and micronebulizers deliver a higher mass of analyte to the plasma but have low limits of detection.24,25 There are new developments in low-flow nebulizers, such as the parallel path nebulizer, and especially the dual nebulizer sample introduction system or multimode sample introduction system,26 which permits direct pneumatic nebulization and/or introduction of vapors (hydrides). Direct injection nebulizers (Vulkan direct nebulizers and direct injection high efficiency nebulizers, DIHN) are becoming common, because they transport nearly 100% of the sample to the plasma, thereby increasing sensitivity.8 However, DIHNs require very low-flow rates of sample uptake, typically <100 μL min-1; with samples containing suspended particulate matter; however, the quality of results may be below the desired level, because this matter can block the instrument. An aerosol generated by nebulization is directed through a spray chamber (nebulizer chamber). This is usually made of glass, quartz, or inert polymers (Ryton or several fluorine-based polymers), which prevents large aerosol droplets from reaching the plasma. The classical Scott chamber design has been superseded by the cyclonic chamber, which has a 50% better sensitivity. 12.2.4.5.1.4 Optics and Detectors Optical components can be arranged in two principal types of instruments: those that measure all wavelengths at the same time (simultaneous spectrometers), and those in which one wavelength is measured after another (sequential spectrometers). The classical optical mounts based on the Paschen–Runge or Czerny–Turner mounts, which used to be the basis of many simultaneous and some sequential spectrometers, have now been superseded by the echelle mount. In such a mount very good resolution is obtained with a mechanically ruled grating, which typically has only 50–100 grooves per mm. Both a prism and a grating are used as crossdispersing media, the former to sort the orders of the VIS range, and the latter to perform this task for the UV range. In such configurations, modern ICP-OES instruments use solid-state detectors, mainly charge injection devices (CIDs) and CCDs. 12.2.4.6 Atomic Fluorescence Spectrometry AFS is based on the absorption of radiation of a certain frequency (the energy transition from the outermost electronic orbitals to a higher energy state) and the subsequent deactivation of the excited atoms with the release of radiation. The most useful type of fluorescence, resonance fluorescence, involves a fluorescence emission radiation of the same wavelength as that used for excitation. Because of the inherent sensitivity of the fluorescence emission process, AFS is one of the most sensitive atomic techniques. All the benefits of AFS are enhanced when this spectrometric technique is used in combination with vapor generation methods, especially for covalenthydride-forming elements. 12.2.4.6.1 Instrumentation 12.2.4.6.1.1 Source of Radiation As the sensitivity in AFS is directly proportional to the source intensity, intense LSs are needed. Typical HCLs are insufficient to guarantee a high intensity of excitation radiation; the previously described EDLs, however, can do so. High-intensity hollow cathode lamps (HI-HCL), first designed by Sullivan and Walsh, are commonly used in modern atomic

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fluorescence spectrometers.27 These are based on HCL, but the atomization and excitation processes, which in earlier lamps occurred over the same cathode, are now kept separate by the use of an additional cathode. In the operation of these lamps, a low current (between 10 and 50 mA) is passed to atomize the element deposited on the cathode; then, a high current (200–500 mA) is supplied by the auxiliary cathode to excite the atoms. With atomization and excitation now taking place over two separate electrodes, the intensity of the lamp is increased by a factor of 20–100. Ongoing developments of HI-HCL have been based on this initial design. Lasers likewise provide highintensity monochromatic radiation to saturate atomic transition. For laser-excited AFS (LEAFS) or laser-induced atomic fluorescence spectrometry (LIF), the laser must be capable of generating wavelengths throughout the VIS and UV regions in order to excite as many elements as possible. In addition, since atomic fluorescence is mainly resonance fluorescence, the use of an ICP, fed with a solution containing elements at high concentrations, provides an alternative quasi-monochromatic radiation source. CSs such as high-pressure xenon-arc lamps can also be used as AFS sources because of the high intensity of the radiation they emit. The use of these lamps eliminates the need to change the source for each element, but the downside is that there are problems with scattering. 12.2.4.6.1.2 Atomizers Flames have usually been used as atomizers for AFS, although plasmas and electrothermal atomizers have been also suggested.28 Typical air–acetylene and nitrous oxide– acetylene flames, as well as hydrogen–argon–air flames, have been used as atomizers for AFS. However, there have been problems with high background signals; attempted solutions of this problem have included the separation of the flame with a quartz tube (torch), or with a shear inert gas (argon), which prevents the entrance of air. Despite the use of these approaches, however, all such flames have a high background emission. Flames in which an inert gas (argon or nitrogen) is burned in hydrogen have low background emissions; but as the temperature of these flames is also low, they are unsuitable for work involving refractory elements. However, the temperature in these flames, commonly known as diffusion flames, is quite sufficient to atomize hydrides, so they are normally used in AFS instruments with HG systems for sample introduction.

12.2.5

MASS SPECTROMETRIC TECHNIQUES

Mass spectrometric techniques are based on the measurement or counting of ions produced at high temperatures. An ion can be identified on the basis of its mass-to-charge ratio (m/z), characteristic of a certain isotope. In addition, quantification is based on the dependence between the number of ions and the concentration of a given isotope in the sample. Mass spectrometers consist of an ion source, a mass analyzer, and an ion detector. The ion source is typically the basis for the different types of mass spectrometric techniques. Plasmas are the most common ion sources for Mass spectrometric elemental determinations, and it is mass spectrometry (MS) using this ion source that will now be described. Complete details of this technique can be found in published monographs.29,30 12.2.5.1 Inductively Coupled Plasma-Mass Spectrometry 12.2.5.1.1 Instrumentation Besides the sample introduction system (a peristaltic pump as in ICP-OES), the basic components for ICP-MS are a horizontally configured (axial configuration) argon plasma torch, which allows the plasma gases to be sampled by the ion analyzer via a differential pumping unit, and the ion analyzer itself, which is a quadrupole/magnetic sector mass spectrometer. The interface (ion sampling interface) between the plasma and the mass analyzer consists of a series of differentially pumped vacuum chambers held at consecutively lower pressures. This interface is needed to extract ions from the hot plasma, which is at atmospheric pressure, into a mass spectrometer at very low pressure (approximately 10-9 atm). The plasma is therefore aligned axially with the tip of a water-cooled, nickel or copper sampling cone with a narrow orifice (1 mm); behind this sampling cone the pressure is reduced to 2 × 10-3 atm by means of a vacuum pump. Plasma gases and analyte ions pass through another metal

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cone aligned axially with the sampling cone (orifice diameter 0.7 mm—the skimmer cone) to an intermediate vacuum chamber held at a pressure of <10-7 atm. At this instant, the ions form a beam that can be focused on to the entrance of the mass analyzer by means of a series of ion lenses. 12.2.5.1.1.1 Mass Analyzers Once in the mass analyzer, the ions are separated in accordance with their different mass-to-charge ratios (m/z). There are three types of mass analyzers: quadrupole, double-focusing magnetic sector, and time of flight (TOF). Quadrupoles consist of four cylindrical metal rods arranged in parallel and operating as electrodes. A combination of RF and direct current (DC) voltages are applied to each pair of opposite rods across a temperature gap of 180°C. Depending on the RF/DC ratio, the electric field allows ions to pass in a certain m/z range. By varying the RF/DC ratio the quadrupole scans the m/z range and allows ions of consecutively higher m/z ratio to pass to the detector. The double-focusing magnetic sector mass analyzer consists of two devices to focus the ion beam: an electric sector analyzer and a magnetic sector analyzer. Ions from the source are accelerated through the entrance slit of the electric sector, which acts as an energy filter. After a narrow band of ions with certain kinetic energies has been selected, the ion beam is focused on to the magnetic sector, where the ions are deflected in accordance with the m/z ratio (a high degree of deflection for ions with high m/z ratios). In the same way as for quadrupoles, a mass spectrum is obtained by scanning the magnetic field and allowing ions of consecutively higher m/z ratio to pass the exit slit of the magnetic sector in the direction of the detector. TOF mass analyzers are based on bombardment by a pulse of electrons or photons to periodically produce positive ions. The pulses have frequencies between 10 and 50 kHz. The generated ions are then accelerated by an electric sector (voltages from 103 to 104 V) at the same frequency as the ionizing bombardment but with a certain gap. The accelerated ions pass to a 1 m long analyzer rod, which is not subjected to an electrical or magnetic field. As all the ions have the same kinetic energy, their velocities along the analyzer rod must be inversely proportional to the m/z ratio. In this way, those ions with lower m/z ratios reach the detector first. The times to reach the detector (the TOF) are between 1 and 30 μs. 12.2.5.1.1.2 Ion Detectors The channel electron multiplier is the usual ion detector for MS. This consists of a curved glass tube (1 mm i.d.), the inner surface of which is coated with a resistive material; the end of the tube is flared. When the instrument is operating in the pulse counting mode (the most sensitive mode), ions are attracted into the funnel opening by a high applied voltage (up to -3500 V). When these ions collide with the inner coating, a significant number of secondary electrons are ejected from the resistive surface and accelerated down the tube. They then collide with the inner walls of the tube and cause further electrons to be ejected from that surface. As a result, an exponential cascade of electrons is produced, which eventually reaches saturation point and results in a large electron pulse (a gain of 107–108 over the original collision). The second operation mode is the analogous mode; this works in a similar way to the pulse counting mode, but lower voltages (between -500 and -1500 V) are applied and the multiplier does not become saturated. The pulses therefore vary in size, and there is a gain of only 103–104. ICP-MS is an attractive technique for multielement determinations. In addition, it allows isotope ratio measurements31 and isotope dilution analysis30 to be carried out. The concepts related to these approaches are, however, beyond the scope of this chapter; the reader will find full details in the literature.30,31

12.2.6

CHEMICAL VAPOR GENERATION-ATOMIC SPECTROMETRY (CVG-AS)

As mentioned at the beginning of this chapter, besides thermal energy to produce atoms, there are chemical methods for obtaining atomic or molecular vapors that are readily atomizable. The atoms generated from these vapors interact with electromagnetic radiation, and the resulting atomic absorption or fluorescence phenomena can be monitored; or else they can be excited and their

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typical emission radiation used for measurement purposes. In this context, Deˇdina and Tsalev32 have written an excellent monograph on HG and AAS. Besides mercury CV and covalent hydrides obtained by chemical reduction, there are other chemical routes that lead to CVG, for example, alkylation, halide generation, metal carbonyl generation, and chelate or oxide generation.33 The classical, CV/HG techniques are thus now known as CVG techniques—this concept includes all possible chemical reactions for generating a chemical vapor (atomic or molecular). According to Sturgeon et al.,33 there has been a resurgence of interest in CVG because the number of elements that can be determined following CVG has increased in recent years. Therefore, to the well-known CVG of mercury, arsenic, selenium, antimony, lead, bismuth, tin, germanium, and tellurium, new elements have been added to the chemical vapor “family,” among them cadmium, chromium, manganese, nickel, copper, silver, and gold.34,35 In addition, fresh developments involving new chelating agents such as thiourea and 8-hydroxyquinoline, UV-assisted CVG approaches, and trapping strategies like solid-phase microextraction (SPME) or single droplet microextraction will ensure that there will be alternatives to the classical CV/HG methodologies. Current CV and HG procedures are based on a reduction reaction using sodium borohydride.36 The decomposition of this reagent at pH < 1.0 is complete within a few microseconds, and the resulting nascent hydrogen reduces analytes to hydrides. The Marsh reaction (most often Zn/HCl), originally proposed for covalent hydrides, and the reaction with tin (II) chloride to obtain mercury CV have been superseded by sodium borohydride/HCl.37 One of the drawbacks of this chemical reduction is that the reduction reaction and the vapor released depend on the valence state of the element. The hydrides of arsenic and antimony respond less vigorously when these elements are in their highest valence state (+5), but the efficiency of HG is close to 100% for the +3 state. Similarly, generating the hydrides of selenium and tellurium is more efficient when these elements are in the +4 state. In such cases, the elements have to be prereduced, usually with potassium iodide, potassium bromide, or l-cysteine; alternatively, the HCl concentration is increased, or heat is applied. For lead, HG efficiency is poor when this element is in the +2 state (the most common valence state of lead). Lead therefore has to be oxidized to the +4 state with hydrogen peroxide prior to reduction; this leads to a substantial improvement in HG.8 When an element is present in the form of different organic species (e.g., arsenic as monomethyl arsenic acid, dimethyl arsenic acid; antimony as trimethyl antimony), the HG process must guarantee that all species are converted into the corresponding hydride. This can be achieved by acid digestion of the water sample or by using reaction solutions, such as thioglycolic acid for arsenic, in which the HG efficiency is independent of the chemical form. Electrochemical hydride generation (EcHG) deserves attention. In addition to the first batch approaches, new EcHG developments based on continuous flow (CF) or flow injection (FI) systems have also been proposed. An electrochemical reduction of hydride-forming elements in solution is achieved in special electrolytic cells, avoiding the use of a reducing agent (sodium borohydride). Lower blanks and lower limits of detection are inherent in EcHG.32,38 12.2.6.1 Instrumentation CVG (CV/HG) methods are based on direct transfer modes, mainly continuous mode—CF or FI—and batch mode.32 If prereduction or oxidation steps are needed, auxiliary lines can be inserted into flow modes to perform these stages automatically before chemical reduction. CF modes deliver the sample and acid to the mixing coil separately, although in many cases the sample can be acidified off-line. FI systems use an injection valve to inject a discrete volume of sample into the carrier (acid) flow. The acidified sample (CF) or the carrier with the injected sample (FI) merges with the reducing solution flow upstream of the reaction coil, where hydride formation takes place. A purging gas (argon) is introduced either upstream or downstream of the reaction coil. Argon introduction upstream is more convenient because of the stripping effect of the purging gas on the hydride vapor released. In batch mode, the acidified sample is transported to a stirred glass cell containing the

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reducing solution or to a plastic vessel without stirring but with an entrance line through which the reducing solution is pumped. After the chemical reduction, the liberated vapor is flushed with the inert gas into the atomizer. Regardless of the chemical vapor transfer mode, CVG uses a gas–liquid separator to separate the chemical vapor from the liquid reagents prior to its introduction into the atomizer. There are several designs of gas–liquid separators, but they can be classified into three basic types: hydrostatic separators, forced outlet separators, and membrane separators. A detailed description of gas–liquid separators will be found in specialized monographs.32 12.2.6.1.1 Atomizers The vapor can be atomized in inert gas-hydrogen diffusion flames, in narrow-bore quartz tubes electrically heated or heated over an air–acetylene flame, and in plasmas. Additionally, the atomizer can act as a vapor preconcentration medium just before atomizing. This is what happens in graphite furnace atomizers (in situ trapping) or on silver or gold wires for direct amalgamation of mercury. Diffusion flames are often argon–hydrogen flames, which are preferable when using atomic fluorescence detectors. These atomizers have several disadvantages, however, such as vapor dilution into the flame gases and background absorption of the flame. Heated quartz tube atomizers are normally T-shaped tubes with the crossbar-tube aligned in the optical path of the spectrometer. These tubes employ either an electrical resistance device or an air–acetylene flame for heating the crossbar-tube of the atomizer; they were the first type to become commercially available. Vapors have also been introduced to plasma-based instrumentation. The sensitivity of the vapor-forming elements increases markedly in comparison with conventional nebulization because of the improved efficiency of transport (close to 100%). Since the first application of a graphite furnace for hydride atomization in 1980, electrothermal atomization has been used for both preconcentration and atomization of trapped vapors.39 The in situ trapping approach uses commercial graphite furnaces as the trapping medium and trapping temperatures from room temperature to around 600°C. Coated graphite tubes, mainly iridium-coated graphite tubes, have been shown to be excellent trapping media for covalent hydrides. The interface used to transfer the vapor from the gas–liquid separator to the graphite furnace is a quartz capillary inserted into the autosampler.40 In modern instrumentation, the capillary is inserted into the graphite furnace when vapor generation starts; on its completion, the capillary is automatically removed from the graphite furnace and atomization can commence. In direct amalgamation, mercury is collected on a silver or gold wire, from which it is released by heating. Both the in situ trapping graphite furnace and gold amalgamation enable very sensitive determinations of vapor-forming elements.

12.2.7

ELECTROCHEMICAL TECHNIQUES

12.2.7.1 Anodic Stripping Voltammetry Voltammetry involves microelectrolytic techniques in which the working electrode potential is forced by external instrumentation to follow a known potential–time function, and the resultant current–potential and current–time curves are analyzed to obtain information about the solution composition. They operate under conditions in which the polarization of the working electrode is at a maximum, which maximizes the variation of the intensity with potential. The working electrode is an ideally polarizable electrode (i.e., the electrode exhibits a large change in potential when an infinitesimally small current is passed through it), such as the dropping mercury electrode (DME). Its surface area is kept as small as possible in order to maintain a high concentration of active species in the adjacent area, and therefore a high level of polarization. A wide variety of voltammetry techniques are available: stripping voltammetry and the voltammetry oxygen sensor are the ones widely applied in the determination of trace metals and dissolved oxygen, respectively. Detailed information on voltammetry methods is given in the monographs by Bard and Faulkner,41 Wang,42 and Brainina and Neyman.43

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Stripping voltammetry is based on the electrochemical deposition or accumulation of analyte at a voltammmetric electrode (anode or cathode) of constant surface during controlled-potential electrolysis. After a certain delay (30 s), the analyte is stripped or dissolved from the electrode by a voltammetric technique or chemical reaction. To give an example, in the first step, the increase in potential causes copper to be electrochemically deposited on the cathode by the reaction: Cu2+ + 2e- Æ Cu; in the second step, when the potential has fallen sufficiently, the deposited copper redissolves as a result of the reverse reaction: Cu Æ Cu2+ + 2e-. A plot of current intensity versus potential gives a peak. If several species are present, there is a peak for each one on the voltammogram (current–potential curve). The potential for redissolving the deposited metal can be used for qualitative purposes, the peak height or area for quantification. ASV is employed for the determination of amalgamate-forming metals (metallic ions) and CSV for determining species that form water-insoluble salts with mercury on the electrode surface. 12.2.7.1.1 Instrumentation The instrument consists of three electrodes: (1) a working electrode that should be easily polarizable, usually a microelectrode based on mercury DME; (2) an auxiliary electrode, usually a platinum wire or a droplet of mercury; (3) a reference electrode, usually a calomel electrode (Hg/Hg2Cl2 and KCl). The DME is a micro working electrode, on which the mercury droplet is formed at the end of a glass capillary (length 10–20 cm; i.d. 0.05 mm). The mercury droplets are of a highly reproducible diameter and have a lifetime from 2 to 6 s. The advantages of the DME are the following: (1) the constant renewal of the electrode surface; (2) the charge-transfer overvoltage of the hydrogen ions present in the aqueous solvent is high on an Hg drop surface; and (3) Hg form amalgams with many metals, thereby lowering their reduction potential. To carry out the measurements, an excess of a strong electrolyte (KCl) is added to the sample; the ionic strength and conductivity thus remain constant. Because oxygen is easily reduced, the dissolved oxygen must be removed: this is done by bubbling an inert gas (N2) for a few minutes and then keeping a stream of nitrogen on the surface to prevent oxygen redissolution. 12.2.7.1.1.1 Voltammetry Sensor: Voltammetry Oxygen Electrode (Clark Electrode) The Clark electrode is a voltammetry sensor capable of measuring the current generated in a redox reaction (a reaction in which dissolved oxygen is involved), which is proportional to the concentration of the dissolved oxygen. This device allows the determination of dissolved oxygen in aqueous samples (fresh water, sea water, blood, sewage, and industrial effluents). It is fitted with a membrane separating the working electrode from the sample solution, thus allowing oxygen to migrate through the membrane. The Clark electrode consists of a platinum disc cathode maintained at a potential of approximately –0.6 V with respect to the annular silver anode surrounding it. A thin (approximately 20 μm) gas-permeable membrane [made from polytetrafluoroethylene (PTFE) or polyethylene] is held in tension across the end of this assemblage such that there is a thin film (~10 μm) between the membrane and the anode and cathode immersed in a buffered KCl electrolyte solution. When the sensor is immersed in water containing dissolved oxygen, molecular oxygen diffuses through the membrane and the internal electrolyte film, and the following electrode processes occur: Cathode reaction: O2 + 4H3O+ + 4e- ´ 6H2O Anode reaction: Ag + Cl-Æ AgCl(s) + eThe diffusion current that flows between the electrodes is proportional to the oxygen concentration. 12.2.7.2 Potentiometric Sensors: ISEs and Gas-Permeable Membrane Sensors Potentiometric sensors are based on a membrane that separates the sample solution of a reference solution contained within the electrode. The membranes are permeable to particular types of ions (ISEs) or gases (gas-permeable membrane sensors). These electrodes generate a potential that is proportional to the concentration of a single analyte. This proportionality is expressed by an equation

Analytical Techniques for the Determination of Inorganic Constituents

277

similar to the Nernst equation. Thus, several dissolved ions or certain dissolved gases (CO2, NO2, SO2, NH3, H2S, HCN, and HF) can be measured with high selectivity and sensitivity. These devices are commonly employed in monitoring studies. Detailed information on ISEs can be found in the monographs by Bard and Faulkner41 and Evans.44 12.2.7.2.1 Instrumentation Potentiometric sensors consist of two electrodes: one is the indicator or membrane electrode (the ion-specific electrode surrounded by a thin film of an intermediate electrolyte solution and enclosed in an ion-permeable membrane), and the other is the reference electrode. Both electrodes are immersed in the sample solution. The indicator electrode consists of an internal reference electrode with an internal filling solution and a membrane located at one end. The membrane separates two liquids, the internal filling solution and the sample solution. The liquid that fills the membrane electrode is a solution containing the ion to be analyzed in the sample, and the concentration of which remains constant. The external sample solution also contains those same ions, but their concentration is unknown. The membrane allows these ions (and only these ions) to migrate through the membrane from both sides. The speed of migration depends on the concentrations of such ions on either side of the membrane. This creates a charge imbalance between the two sides, which is reflected by the emergence of a potential. Since the potential due to the reference electrode is constant, signal variations are attributed only to the potential dependent on the ion concentration in the sample solution. All these considerations, along with the implementation of the relevant equations, lead to the conclusion that the potential measured by a potentiometer connected to the two electrodes is the sum of a constant value EK plus a value depending on the concentration of the ion in the sample solution, according to the following Nernstian expression:

( )

RT ln C, Emeasured = Ek + ___ nF

(12.1)

where C is the analyte concentration, the value of EK encompasses all potential constants and can be determined after calibration, R and F are constants (8.314 JK-1 mol-1 and 96,485 C mol-1, respectively), and T is the temperature expressed in K. Membranes are made of glass or a glass of a particular compound and certain insoluble polymers filled with certain liquids. Each membrane electrode is designed for the specific measurement of a particular ion. The fluoride (F-) ISE, for example, contains an Ag/AgCl electrode immersed in a solution of NaCl and NaF and a membrane glass made from LaF3. ISEs have also been designed for the determination of Cl-, Br-, I-, CN-, SCN-, NO3-, S2-, Ag+, Cd2+, Ca2+, Pb2+, and so on. Table 12.1

TABLE 12.1 ISE Glass Membranes Target Analyte

Membrane

F

-

LaF3

Cl-

AgCl

Br-

AgBr

I-

AgI

CN-

AgI

SCN-

AgSCN

Ag+/S2-

Ag2S

Cu2+

Ag2S (CuS)

Cd2+

Ag2S (CdS)

Pb2+

Ag2S (PbS)

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TABLE 12.2 Types of Potentiometric Dissolved Gas Sensors Based on ISEs Target Analyte

Equilibrium in the Internal Solution

Sensing Electrode

CO2

CO2 + 2H2O ´ HCO3 + H3O

pH glass

NO2

2NO2 + 3H2O ´ NO2- + NO3- + 2H3O+

pH glass

SO2

SO3 + 2H2O ´ HSO3- + H3O+

pH glass

NH3

NH3 + H2O ´ NH4+ + OH-

pH glass

H 2S

H2S + 2H2O ´ S2- + 2H3O+

Ag2S (S2-) ISE

HCN

HCN + H2O ´ CN- + H3O+

HF

HF + H2O ´ F- + H3O+

Ag2S (Ag+) ISE LaF3 ISE

-

+

lists the membranes used in some ISE electrodes. Finally, protons (H3O+) can be detected by this technique, which permits pH measurements. There are also potentiometric sensors that detect molecules, especially gases and certain biochemical molecules. Gas-permeable membrane sensors usually incorporate a conventional ISE surrounded by a thin film of an intermediate electrolyte solution and enclosed in a gas-permeable membrane. An internal reference electrode is usually included; so the sensor represents a complete electrochemical cell. Gas-permeable membranes are usually made of polymeric materials and are from 10 to 100 μm thick. Highly selective, gas-permeable membranes allow the gas to migrate through the membrane and then to react with the reagent contained within. The reaction usually generates or consumes protons, the numbers of protons generated or consumed being proportional to the concentration of dissolved gas. There are applications for gases such as CO2, NO2, NH3, HCN, HF, H2S, and SO3 in water. Gas-permeable membrane sensors are remarkably selective and sensitive devices; the most commonly used ones are shown in Table 12.2.

12.2.8

SEPARATION TECHNIQUES

IC and CE are the most commonly applied separation techniques for the determination of inorganic ions. 12.2.8.1 Ion Chromatography IC is a liquid chromatography subclass in which analyte separation is based on ion-exchange mechanisms. Analytes interact with both the stationary phase (ion-exchange resin) and the mobile phase. The full details of liquid chromatography, especially IC, will be found in the literature.45,46 IC is based on the ion-exchange equilibrium between the ions in solution and those on the surface of a solid—an ion-exchange resin (the stationary phase). The resins are polymers (typically, a styrenedivinylbenzene copolymer) that contain chemical groups capable of capturing an anion or cation from the solution and at the same time releasing OH- or H+ ions, respectively. The ion-exchange resin can be either a strong or a weak cation/anion exchanger. The exchange capacity of the resin also depends on the number of ionic groups that it carries. There are cation exchange resins (containing sulfonic groups, -SO3- H+ or carboxylic groups, -COO- H+) and anion exchange resins (containing -NR3+ OH- groups, where R = H or CH3). These resins are deposited on nonporous microparticles of glass or polymers, or on porous silica. When an ion-exchange resin with sulfonic acid groups is in contact with an aqueous solution containing cations, M x+, the ion-exchange equilibria can be described as follows: xRSO3- H+ (solid) + M x+ (solution) ´ (RSO3-)x M x+ (solid) + xH+ (solution),

Analytical Techniques for the Determination of Inorganic Constituents

279

where RSO3- H+ represents one of the many sulfonic acid groups bonded to the polymer. In a similar way, an anion exchange resin interacts with anions, A x-, according to the following equilibrium: +

xRN(CH3)3 ·OH (solid) + A x- (solution) ´ [Rh(Ch3)3+]xA x- + xOH-.

The mobile phases are usually aqueous solutions that contain a competing ion carrying the same charge as the analytes to be separated. These competing ions displace the analyte ion from the stationary phase and finally elute the analytes from the column. During the separation, the analyte ions compete with the ions in the eluent for the charged sites on the stationary phase. The separation is based on an adsorption–desorption process between the analyte and the ionic groups of the stationary phase. The most crucial parameters for the separation are the nature of the resin, the pH, and the ionic strength of the eluent. 12.2.8.1.1 Instrumentation Since IC is a type of high-performance liquid chromatography (HPLC) in which the stationary phase is an ion-exchange resin, an IC instrument is similar to a typical HPLC. It consists of (1) a pump unit; (2) solvent reservoirs; (3) an injector; (4) a chromatographic column; and (5) a detector. The principle of operation is simple. The pump pushes the eluent (mobile phase) through the column at a certain flow rate. For injecting the sample, the eluent passes through the injector and transfers the sample to the column. The sample components are separated in the column, each of which is then successively detected by the detector. The pumps (usually reciprocating pumps and displacement pumps) produce pressures up to 400 bar (40 MPa) covering a large range of flow rates (0.1–10 mL min-1) with a high degree of precision and no pulsation. Solvents should be filtered before use to remove suspended particles. Similarly, dissolved gases must also be removed by out-gassing with helium or nitrogen or by processing in ultrasonic baths. The solvents used as the mobile phase are stored in glass or stainless steel reservoirs. The instrument enables operation with a constant solvent composition (isocratic elution) or with a variable solvent composition (gradient elution). The sample injection system allows the injection of sample volumes from 1 to 500 μL. To prevent depressurization of the system, samples are injected through special six-way valves to which a sample loop has been attached. The sample is injected directly into the loop by means of a microliter syringe (filling position) while the eluent flows to the column. The eluent flow is then directed via the sample loop to the column when the valve is switched to the injection position. The column length varies from 3 to 30 cm, the inner diameter from 1 to 10 mm. Columns are made of very resistant materials to withstand high pressures (<40 MPa): Most commonly, a stainless steel or heavy-walled glass tube is inserted into a metal tube. Columns are packed with a solid material of particle size <10 mm (spherical and nonporous microglass beads or polymer particles). A guard column is usually placed before the column to remove suspended particles from solvents, as well as certain sample constituents that could irreversibly bind to the stationary phase. Conductivity and photometric detectors (detection of ionic conductivity or the color of the mobile phase, respectively) are used as IC detectors. The low sensitivity is the main disadvantage of the conductivity detector, because the conductivity of the mobile phase (buffered solution) is strong and tends to mask that due to analytes. This detection problem has been solved by coupling a suppressor column or an exchange membrane to the analytical column. These devices convert mobile phase ions (e.g., carbonate, bicarbonate, and hydroxide) into their weakly conducting conjugate acids, thereby decreasing the conductivity. Since the analyte ions do not react in the suppressor, their conductivity can be detected at very low levels. After a certain time, the suppressor column has to be regenerated—this is the main shortcoming of this approach. The suppressor column is unnecessary if a direct or indirect photometric detector is used. Indirect photometric detection uses a UV-VIS absorbing substance that provides a constant background absorption. Ions eluted from the column displace the absorbing substance and are measured indirectly. Direct photometric detection uses a complex-forming agent that is mixed with the eluent. This remains colorless during the flow of the

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pure mobile phase. However, metal-complex formation takes place when metal ions are present in the eluent, and the intense color of such complexes can be distinguished from the colorless background. 12.2.8.2 Capillary Electrophoresis Separations by electrophoresis are based on the differential migration of solutes in an electrical field. In CE, electrophoresis is performed in narrow-bore capillaries, typically of 25–75 μm i.d., which are usually filled with a buffer solution. There are several advantages accruing from the use of capillaries, related mainly to the detrimental effects of Joule heating. The high electrical resistance of the capillary enables the application of very powerful electrical fields (100–500 Vcm-1) with only minimal heat generation. The use of strong electrical fields results in short analysis times together with high efficiency and resolution. In addition, several separation modes with different separation mechanisms and selectivities are available, sample volume requirements are minimal (1–10 nL), and in-capillary detection is possible. It may also be possible to apply CE to quantitative analysis, and to automate the technique. Detailed descriptions of CE and its principal applications can be found in the monographs by Morteza47 and Shintani and Polonsky.48 Separation by electrophoresis is based on solute velocity differences in an electrical field. The velocity of an ion, v, can be given by v = μeE, where additionally μe is the electrophoretic mobility and E is the applied electrical field. The electrical field is a function of the applied voltage and the capillary length. For a given ion and medium, the mobility is a constant characteristic of that ion. It is determined by the electric force exerted on the ion, balanced by its frictional drag through the medium, that is, μe a FE/FF, where FE is the electrical force and FF is the frictional force. The electrical force is given by FE = qE and the frictional force (for a spherical ion) by FF = - 6phrv, where q is the ionic charge, h is the viscosity of the solution, r is the ionic radius, and v is the ionic velocity. During electrophoresis, a steady state defined by the balance of these forces is attained. At this point the forces are equal but opposite, and qE = 6phrv. Since v = μeE, the mobility can be described by physical parameters such as μe = q/6phr. From this last equation it is evident that the mobilities of small, highly charged species are high, whereas those of large, minimally charged species are low. Another fundamental aspect of CE separation is electro-osmotic flow (EOF). EOF is the bulk flow of liquid in the capillary and is a consequence of the surface charge on the inner capillary walls. EOF results from the effect of the applied electric field on the solution double-layer at the wall. It governs the amount of time that solutes remain in the capillary by the superposition of flow on to soluble mobility. This can have the effect of altering the required capillary length, but it does not affect selectivity. The magnitude of EOF can be expressed in terms of velocity or mobility by VEOF = (ez/h) E or μEOF = (ez/h), where VEOF is the velocity, μEOF is the EOF “mobility,” e is a dielectric constant, and z is the zeta potential. The zeta potential is determined essentially by the surface charge on the capillary wall. Since this charge is strongly pH dependent, the magnitude of EOF varies with the pH. The zeta potential is also dependent on the ionic strength of the buffer solution, as described by the double-layer theory. A unique feature of EOF in the capillary is the flat profile of the flow. Since the driving force of the flow is uniformly distributed along the capillary (i.e., at the walls), there is no pressure drop within the capillary, and the flow is nearly uniform throughout. This is in contrast to the pressure generated by an external pump, which yields a laminar or parabolic flow owing to the shear force at the wall. 12.2.8.2.1 Instrumentation One key feature of CE is the overall simplicity of the instrumentation. Briefly, the ends of a narrowbore, fused silica capillary (25–75 μm i.d., 350–400 μm o.d., and 10–100 cm in length) are placed in buffer reservoirs. The content of the reservoirs is identical to that within the capillary. The reservoirs also contain the electrodes used to make electrical contact between the high voltage power supply and capillary. The sample is loaded into the capillary as follows: one of the reservoirs (usually at the anode) is replaced by the sample reservoir and either an electric field (electrokinetic

Analytical Techniques for the Determination of Inorganic Constituents

281

injection) or external pressure (hydrodynamic injection) is applied. When the buffer reservoir has been replaced, the electric field is applied and the separation performed. Optical detection (UV-VIS and fluorescence absorption) can be done at the opposite end, directly through the capillary wall. The versatility of CE is derived partially from its numerous modes of operation, that is, capillary zone electrophoresis (CZE), micellar electrokinetic chromatography (MEKC), capillary gel electrophoresis (CGE), capillary isoelectric focusing (CIEF), and capillary isotachophoresis (CITP). Of these, CZE is used most often for charged ions or molecules because of its great simplicity and versatility.

12.2.9

AUTOMATIC ANALYZERS AND MONITORING

One of the major advances in analytical chemistry in recent decades has been the emergence on the market of automated systems for analysis (automatic analyzers), which provide analytical data with minimal operator intervention. Automation implies the partial or complete replacement of human involvement in an operation or sequence of operations. The monographs by Valcárcel and Luque de Castro49 offer detailed descriptions of automatic analyzers. Initially, these systems were designed to address the needs of clinical laboratories, but at present they are used in such diverse areas as industrial process control (process analyzers) or routine determinations of various substances in the air, water, and soil (environmental monitoring). Automatic analyzers can be classified according to the way in which samples are transported and manipulated: 1. Discrete or batch analyzers: In these, each sample preserves its integrity in a vessel transported mechanically to various zones of the analyzer, where the different analytical stages are carried out in a sequential manner. Each sample finally arrives at the detector where the relevant signals are recorded. 2. Continuous analyzers: They are characterized by the use of a continuous stream of liquid. The samples are sequentially introduced at regular intervals into a channel carrying a liquid that does or does not merge with other channels carrying reagents, buffers, masking agents, and so on, upon reaching the detector. The final reaction mixture yields an analytical signal that is duly recorded. There are two types of continuous analyzers for segmentedflow analysis (SFA) and unsegmented-flow analysis. SFA are characterized by a segmented flow of air bubbles, the aim of which is to preserve the integrity of samples. Unsegmentedflow analysis, mainly flow injection analysis (FIA) and continuous flow analysis (CFA), provide a flow that is not segmented by air bubbles. Batch analyzers can be classified according to the manner in which the sample is transferred to the final operation, that is, with or without final transfer of the sample. In analyzers with final transfer, the reaction mixture is transported to the detection system, where the analytical measurement is carried out in a fixed cuvette. In analyzers without final transfer of the reaction mixture, all the stages of the process take place in the same vessel. In SFA, the bubbles prevent contamination between successive samples, reduce sample dispersion, and facilitate mixing of sample and reagents in a way that enables physical and chemical equilibrium to be attained before the sample reaches the detector. The main elements of these analyzers are as follows: 1. A sampling system: Sampling is carried out with the aid of a moving aspirating tip; air bubbles are also aspirated between samples. 2. A propelling system: This is a peristaltic pump used to propel fluids along continuous segmented systems—flexible plastic tubing is squeezed by a series of rollers, which starts the flow of the enclosed liquids as a result. These systems can work with several streams, and the flow rate is determined by the internal diameter of the tube and the pump rotation speed.

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Analytical Measurements in Aquatic Environments

3. A reaction system: This consists of helically coiled tubes of a given diameter that are connected to the other elements of the system. 4. A separation unit: Devices that permit continuous separation techniques, for example, dialyzers, filters, adsorbent columns, and exchange resins. 5. A debubbler: A high-precision device that removes the bubbles. This device is not essential if certain software treatments that discriminate signal parasites caused by bubbles are used. 6. A detection system: This consists of a flow cell located in the optical or electroanalytical instrument. Single-channel (for the determination of one analyte) or multichannel configuration (for several analytes) can be used. In FIA, the sample and reagents are incompletely mixed and there is a concentration gradient that varies along the system as a function of time. The continuous detectors provide a transient signal, which is recorded. Neither physical equilibrium (homogenization of a portion of the flow) nor chemical equilibrium (reaction completeness) is attained by the time the signal is detected. Hence, FIA can be considered a fixed-time analytical methodology. The main elements of these analyzers are 1. A propelling system: A peristaltic pump 2. An injection system: A six-way rotary valve (three inlets and three outlets) that can adopt two positions—in the filling position the sample fills the loop; in the injecting position, the carrier sweeps the sample toward the reactor) 3. A transport and reaction system: Small tubes of between 0.1 and 2 mm i.d 4. A detector system: Optical or electroanalytical instruments CFA is similar to FIA. The main difference between CFA and FIA is the long analysis time required to stabilize the hydrodynamic conditions. In addition, other differences are the use of large i.d. tubes, faster flow rates, and special requirements for the rinsing stages. Many of the automatic analyzers described have been adapted to automatic water analysis (offline and on-line water analyzers) to facilitate the analysis and monitoring of the inorganic constituents of water (Chapter 18). On-line water analyzers can claim a number of advantages over off-line analyzers: sampling is more representative, the risk of contamination by containers or changes in sample composition during storage is minimal, and the evolution of the system under study can be continuously monitored. A great number of instruments are commercially available for monitoring parameters (multiparameter analyzers) such as pH, pCl, redox potential, conductivity, dissolved oxygen, temperature, cyanide, sulfide, ammonia, nitrites, nitrates, salinity, metals, and so on. In these automated analyzers, the sample is injected or merged into a carrier stream that subsequently mixes with one or more reagent streams. The mixture solution can be detected by a variety of flowthrough detection techniques, such as spectrophotometry, fluorescence, atomic absorption, potentiometry, and voltammetry.

12.3 DETERMINATION OF INORGANIC CONSTITUENTS A great number of different standard and nonstandard analytical methods are available for the determination of inorganic constituents in water. Since the concentrations of some inorganic constituents are relatively high in water, classical methods (gravimetry and titration) were mostly used in early experiments. These methods, however, have been largely replaced, chiefly by faster, more sensitive, and more sophisticated instrumental methods. Tables 12.3 through 12.8 summarize different standard or official methods for the determination of inorganic constituents. Table 12.3 shows the main procedures for nutrient determinations; it can be seen that UV-VIS spectrophotometry50-52,58-60 and ISE50,53,54,56 are the most commonly used analytical techniques.

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Analytical Techniques for the Determination of Inorganic Constituents

TABLE 12.3 Selected Standard and Official Methods for the Determination of Nutrients Analyte

Analytical Technique

NO3-

UV

Direct measurement at 220 nm. Additional reagents not required

VIS

Nitrate is reduced to nitrite (by cadmium reduction reaction), which is then determined by diazotization (pH = 2.0–2.5) with sulfanilamide and coupling N-(1-naphthyl)-1,2-ethylendiamine hydrochloride to form an intensely pink colored azo dye (540 nm) Brucine oxidation by nitrate ion in H2SO4 at 100°C to form a yellow compound (cacoteline), which is measured at 410 nm

VIS

Details of Method

Analytical Characteristics

Reference

Applicable to unpolluted samples with a low content of organic matter. Samples should be filtered to avoid interference from suspended particles or colloidal matter and organic compounds. Several ions (Br-, SCN-, I-, CO32-, NO2-, Fe2+, Fe3+, and Cr(VI)) may be important interferents Metals at high concentrations (around mg L-1) diminish reduction efficiency. Residual Cl2 interferes through cadmium oxidation

50

Applicable to 0.1–2 mg L-1 in surface, saline, domestic, and waste water. Strong oxidizing and reducing agents interfere (NaAsO3 in addition to residual Cl2 removal). Effect of Fe2+, Fe3+, and Mn4+ is negligible at <1 mg L-1

51

50

ISE

Direct potentiometric determination by using a NO3--ISE

Applicable to 10-5–10-1 M. Interferents (Cl-, Br-, I-, S2, CN-, NO2-, and organic acids) are minimized by using Ag2SO4 buffer, sulfamic acid, and Al2(SO4)3

50

NO2-

VIS

Nitrite reacts with sulfanilamide to form a diazo compound; this couples with N-(1-naphthyl)-1,2ethylendiamine hydrochloride in an acidic medium to form an intensely pink colored azo dye (540 nm)

Applicable up to 0.25 mg L-1 in surface, tap, and waste water. High alkalinity, Cl-, Cl2, S2O32-, PO43-, and Fe3+ may be important interferents

50,52

NH4+

Acid–base titration

NH4+ is distilled after alkalinization. Titration with standardized 0.01 M H2SO4 and a mixed indicator (methylene blue and methylene red)

Applicable to 1.0–25 mg L-1 in surface, saline, domestic, and waste water. Volatile alkaline compounds interfere

50,51,53– 55

VIS

NH4+ is distilled from water after alkalinization. Ammonium reacts with Nessler’s reagent (I2Hg—2IK) to form a yellow-brown colored complex (410–425 nm)

Applicable to 0.05–1 mg L-1 in surface, saline, domestic, and waste water.

50,51

continued

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Analytical Measurements in Aquatic Environments

TABLE 12.3

(continued)

Analyte

Analytical Technique

Details of Method

ISE

ISE

Direct potentiometric determination by using an ammonia-sensing membrane probe

Kjeldahl nitrogen

Acid–base titration and VIS

Total dissolved nitrogen

VIS

Kjeldahl nitrogen is the sum of nitrogenous organic compounds, free ammonia, and ammonium. In the presence of H2SO4, K2SO4, and selenium catalyzer; organic nitrogen is converted to ammonium. Free ammonia is also converted to ammonium. After the addition of a base, the ammonia is distilled from an alkaline medium and absorbed in boric acid. The ammonia may be determined colorimetrically at 655 nm or by titration with a standard mineral acid Alkaline peroxodisulfate oxidation, all N (free ammonia, ammonium, nitrate, nitrite, and nitrogenous organic compounds) is converted into nitrate. Nitrate is reduced to nitrite (by cadmium reduction reaction). Nitrite reacts with sulfanilamide and N-(1-naphthyl)1,2-ethylendiamine hydrochloride to form an azo dye, which is measured at 540 nm

PO43-

VIS

Si

Gravimetry

Reaction of PO43- with acidified molybdate reagent (in the presence of potassium antimonyl tartrate) to yield H3PO4(MoO3)12, which is reduced by ascorbic acid to the intensely blue-colored compound phosphomolybdenum blue and measured at 840 nm This involves a combined process of evaporation, baking, and ignition. Organic matter is removed by ashing, followed by digestion with hydrochloric acid, leaving a residue of insoluble silica

Analytical Characteristics

Reference

50,53,54 Applicable to 0.03–1400 mg L-1 in surface, saline, domestic, and waste water Applicable to ammonium nitrogen 56 concentration of up to 50 mg L-1 in raw and waste water and sewage Applicable up to 10 mg in tap, 51,57 natural, and waste water. Nitrate and nitrite may interfere

Applicable to 0.02–5 mg L-1 in tap, surface, natural, sea, and waste water

50,58

Applicable to 0.01–0.5 mg L-1 in surface and saline waters. High concentrations of Cu, Fe, silicate, and arsenate do not interfere

50,51,59

This procedure gives the total silicon content in water samples; only approximate results are obtainable

51

continued

285

Analytical Techniques for the Determination of Inorganic Constituents

TABLE 12.3

(continued)

Analyte

Analytical Technique VIS

Details of Method Reaction with molybdate to form yellow silicomolybdic heteropolyacid (H4SiMo12O40), which is then reduced (by sodium metabisulfite and 1-amino-2naphthol-4-sulfonic acid) to colored silicomolybdenum blue and measured at 810 nm

Analytical Characteristics -1

Applicable to >1.0 mg L in natural and waste water. This procedure gives the soluble silicate content after filtration. Oxalic acid is added to minimize interference from phosphate

Reference 50,60

Ammonium and Kjeldahl nitrogen are determined by acid–base titration50,51,53-55,57 and silica by gravimetry.51 IC (Table 12.4) is also used for the simultaneous determination of nutrients and major ions, halides, cyanide, and sulfur compounds.50,51,54,61-66 Table 12.5 lists other standard methods for the determination of major ions: carbonate and bicarbonate (alkalinity)50,51,67, 68 and calcium and magnesium (hardness).50,51,70-72 Table 12.6 sets out other standard methods for the determination of nonmetallic substances: chloride is determined by titration,50,51,73 VIS spectrophotometry,50,74 and ISE;51 chlorine by titration and VIS spectrophotometry;75-77 fluoride by VIS spectrophotometry50 and ISE;50,78,79 iodide by VIS spectrophotomtery;50 cyanide by titration, VIS spectrophotometry, and ISE;50,80,81 sulfate by gravimetry50,51 and turbidimetry;50 sulfite by titration and VIS spectrophotometry;51 and sulfur by titration and VIS spectrophotometry.50,51 TABLE 12.4 Selected Standard and Official Methods Using IC for the Determination of Nutrients, Major Ions, Halides, Cyanide, and Sulfur Compounds Analyte Br -, Cl-, F-, NO2-, NO3-, PO43-, SO42-

Analytical Technique

Details of Method

Analytical Characteristics

IC

Anions are separated using a guard column, separator column, and suppressor device; they are measured using a conductivity detector. UV and an amperometric detector are also used

Applicable to tap, rain, surface, ground, and waste water. Carboxylic acids (malonic, maleic, malic, formic, and acetic acid) at high concentrations and carbonate may be important interferents Applicable to tap, surface, and waste water. Amino acid and aliphatic amines may be important interferents Mono- and dicarboxylic acids and sulfate may be important interferents Mono- and dicarboxylic acids, F-, Br -, Cl-, CO32-, NO2-, and NO3- may be important interferents

Li+, Na+, NH4+, K+, Mn2+, Ca2+, Mg2+, Sr2+, Ba2+ CrO42-, I-, SO3-, SCN-, S2O32ClO3-, Cl-, EClO2-

Anions

CE

Anions are separated using CE and quantified by indirect UV detection

Reference 51,54,61–63

64

65

66

50

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Analytical Measurements in Aquatic Environments

TABLE 12.5 Other Standard Methods for the Determination of Major Ions Analytical Technique

Details of Method

Alkalinity: CO32-, HCO3-

Acid–base titration

Ca2+

EDTA titration

Titrating with standardized 0.01 M H2SO4 using phenolphthalein as indicator until the pink color disappears at about pH 8.3; titration of the same sample is then continued until the end point is reached at pH 4.5 using a bromocresol green-methyl red mixed indicator (total alkalinity) Titrating with standardized 10 mM EDTA at pH 12–13 using HSN as indicator

Hardness: Ca2+, Mg2+

EDTA titration

Ca2+, Mg2+

FAAS

Analyte

Titrating with standardized 0.01 M EDTA at pH 10 using eriochrome black T or calmagite as indicators Ca and Mg are measured by FAAS at 422.7 nm and 258.2 nm, respectively, using air/ C2H2 or NO2/C2H2 flames

Analytical Characteristics

Reference

Applicable to natural and waste water. Concentrations of bicarbonate, carbonate, and hydroxide can be calculated. The titration end points can be measured potentiometrically

50,51,67–69

Applicable to 2–100 mg L-1 in tap, surface, ground, and waste water. Interferences from Al, Ba, Co, Cu, Fe, Mn, Pb, Sb, and Zn can be removed by the addition of cyanide and triethanolamine Al, Ba, Cd, Co, Cu, Fe, Mn, Ni, Pb, Sr, and Zn interferents can be removed by the addition of NaCN or Na2S

50,70

Applicable to 3–50 mg Ca L-1 and 0.9–5 mg Mg L-1 (interferences due to ionization are removed mainly by the use of CsCl or LaCl3)

50,51,71

72

TABLE 12.6 Other Selected Methods for the Determination of Non-Metallic Substances Analyte Chloride

Analytical Technique

Details of Method

Analytical Characteristics

Reference

Mercuric nitrate titration

Chloride titration with mercuric ions to form soluble and slightly dissociated HgCl2 (pH 2.3–2.8 and diphenylcarbazone as indicator).

Chromate, Fe3+, and SO32interfere when levels are >10 mg L-1. Sulfite may be removed by the addition of H2O2.

50,52

Argentometric titration

Titration with silver nitrate standardized (0.0141 M) against 0.014 M NaCl using potassium chromate as indicator. The end point is indicated by the formation of the yellowish pink precipitate of Ag2CrO4.

Applicable to 0.15–10 mg L-1 in clear waters. Br-, I-, CN-, H2PO4-, and Fe interfere. Sulfide, sulfite, or thiosulfate interferents can be removed by oxidation with a small amount of H2O2.

50,73

continued

287

Analytical Techniques for the Determination of Inorganic Constituents

TABLE 12.6 Analyte

(continued) Analytical Technique

VIS

Potentiometric titration

Free chlorine and total chlorine

Titration

VIS

Details of Method Chloride ions react with mercury (II) thiocyanate to form a sparingly dissociating mercuric chloride complex and liberate a stoichiometrically equivalent amount of thiocyanate ions (2Cl- + Hg(SCN)2 → HgCl2 + 2SCN-); the thiocyanate reacts with iron (III) ions, yielding the intensely red ferric thiocyanate complex (SCN-+ Fe3+ → Fe(SCN)2+), which is determined at 460 nm. The sample is titrated with standardized silver nitrate (0.0141 M) in a continuously mixed beaker with an Ag electrode, an Ag/ AgCl electrode, or a chloride–-ISE. The reference can be a glass mercuric sulfate, calomel, or Ag/ AgCl electrode. Free chlorine is defined as the concentration of residual chlorine in water present as the dissolved gas (Cl2), hypochlorous acid (HOCl), and/ or hypochlorite ion (OCl-). Free chlorine reacts with N,N-(1naphthyl)-1,2-ethylendiamine hydrochloride (at pH 6.2–6.5) to form a red compound, which is titrated with a standardized solution of ammonium and ferrous sulfate until the red color of the solution disappears. Total chlorine is the sum of free and combined chlorine (defined as the residual chlorine existing in water in chemical combination with ammonia or organic amines). Total chlorine reacts with N,N-(1-naphthyl)-1,2ethylendiamine hydrochloride and potassium iodide; the compound formed is titrated as stated above. Free chlorine reacts with N,N-(1naphthyl)-1,2-ethylendiamine hydrochloride (at pH 6.2–6.5) to form a red compound, which is determined at 510 nm Total chlorine reacts with N,N-(1naphthyl)-1,2-ethylendiamine hydrochloride and potassium iodide; the compound formed is determined at 460 nm.

Analytical Characteristics

Reference

The presence of Br , I , CN , S2O32-, S2-, SCN,-, and NO2- interferes. The method can be applied in the 0.01––10 mg L--1 concentration range.

50,74

Applicable to 0.15–10 mg L-1 in colored or turbid waters. Iodine and bromide interfere by forming a less soluble precipitate with the silver ions. [Fe(CN)6]3+, CrO42-, Cr2O72-, and Fe3+ interfere.

50

Applicable to 0.03–5 mg L-1 (expressed as Cl2) in surface and sea water.

75

Applicable to 0.03–5 mg L-1 (expressed as Cl2) in surface and sea water.

76

-

-

-

continued

288

Analytical Measurements in Aquatic Environments

TABLE 12.6 Analyte

(continued) Analytical Technique

Total chlorine

Iodometric titration

Fluoride

ISE

VIS

Iodide

VIS

Cyanide

Argentometric titration

VIS

Details of Method Total chlorine reacts with potassium iodide to produce iodine, which is titrated with an excess of a standardized sodium thiosulfate solution. The excess thiosulfate is back-titrated with standardized potassium iodate solution. Direct potentiometric measurement: europium-dosed lanthanum fluoride crystals electrode can be used for direct fluoride measurement. A high concentration of background electrolyte (TISAB) is added to the ionic-strength-adjusting buffer to maintain the pH at 5–7.0. Fluoride reacts with colored zirconium-SPADNS complex: Fforms the colorless ZrF62- complex; absorbance of the zirconiumSPADNS complex measured at 570 nm decreases as the fluoride concentration increases. Iodide is selectively oxidized to iodine by the addition of KHSO5. The liberated iodine selectively oxidizes leuco crystal violet to form crystal violet in neutral medium (pH = 6.5). The color of the dye is measured at 592 nm. Cyanide is titrated with silver nitrate standardized solution to form a soluble cyanide complex (Ag[Ag(CN)2]). The end point is shown by a silver-sensitive indicator (p-dimethylaminobenzalrhodanine), which reacts with the small excess of Ag ion. The color of the solution turns from yellow to red. Cyanide absorbed in sodium hydroxide (previous distillation) is treated with chloramines-T to produce cyanogen chloride (CNCl). Addition of pyridine-barbituric acid produces a red-blue product with an absorbance maximum at 575–582 nm. An alternative method involves the reaction of CNCl with chloramine-T, pyridine-pyrazolone, and a phosphate buffer to produce a blue product that is determined at 620 nm.

Analytical Characteristics

Reference

Applicable to 0.71–15 mg L (expressed as Cl2) in surface water.

50,77

Applicable to 0.2 mg–20 g L-1 in tap, natural, surface, and waste waters. Cyclohexylenediaminetetraacetic acid (CDTA) is added to complex interfering cations such as Ca, Mg, Fe, and Al and release free fluoride ions.

50,78,79

Potential interferences in this method from high alkalinity, aluminum, iron, and phosphate.

50

Applicable to 50–6000 μg L-1. Chloride (at concentrations >200 mg L-1) interferes.

50

Applicable to water containing <50 mg L-1 (<100 mg of total cyanide L-1).

50,80,81

Applicable to water containing <50 mg L-1 (<100 mg of total cyanide L-1). Thiocyanate and sulfide interfere. Sulfide is removed by precipitation (as cadmium sulfide) by the addition of cadmium carbonate.

50,80,81

-1

continued

289

Analytical Techniques for the Determination of Inorganic Constituents

TABLE 12.6 Analyte

Sulfate

Sulfite

(continued) Analytical Technique

Details of Method

Analytical Characteristics

ISE

Direct potentiometric measurement: an AgI membrane electrode with a double junction reference electrode system must be used to quantify CN-.

Transition metal cations interfere by forming stable complexes. Chloride and bromide also interfere. Interference from sulfide is removed by the addition of 10 M NaOH ISA .

50

Gravimetry

Analysis of precipitated barium sulfate after reaction with barium chloride.

50,51

Turbidimetry

Sulfate is precipitated with BaCl2 in dilute HCl with constant stirring (60 s). The turbidity of the suspension formed is related to the sulfate concentration.

Iodometric titration

Titration with standardized iodide– iodate (0.0125 N). Free iodine is produced when the iodide–iodate reagent reacts with sulfite, and in the presence of a starch indicator, the first excess produces a blue color that signals the end point. The method involves the purging of SO2 from an acidified sample with nitrogen gas for about 1 h. The SO2 is trapped in a solution of Fe3+ and 1,10-phenanthroline. The Fe2+ produced by the reaction with SO2 is detected at 510 nm. Back-titration of iodine with standard sodium thiosulfate. Iodine is added to oxidize sulfide under acidic conditions.

Applicable to >10 mg L-1 in natural and waste water. This method is time-consuming and susceptible to interference from suspended particulate matter, silica, nitrate, sulfite, sulfide, and alkali metals. Applicable to surface and industrial water and suitable for the detection of sulfate at 1 mg L-1 or more. Color, suspended matter, silica, and sulfite interfere. Some suspended matter is removed by filtration. Glycerine and NaCl solution are added to stabilize the slurry and minimize interferences. Applicable to natural and waste water. There may be interference from S2-, Fe2+, and thiosulfate that leads to overestimation of sulfite, or from the presence of ions (Cu2+) that catalyze the conversion of sulfite to sulfate.

VIS

Sulfide

Iodometric titration

VIS (methylene blue method)

Reaction of sulfide, ferric chloride, and dimethyl-p-phenylenediamine to produce methylene blue, which has lmax at 660 nm.

Reference

50,51

50

51

Applicable to >1.0 mg L-1 in natural, hot spring, and waste water. Reducing agents (thiosulfite, sulfite, and organic compounds) may interfere.

50,51

Applicable to <20 mg L-1 in natural and waste water. Ammonium phosphate must be added to mask interferences of residual ferric chloride. The effect of other interferents (reducing agents and thiosulfate) may be important.

50

continued

290

Analytical Measurements in Aquatic Environments

TABLE 12.6 Analyte

(continued) Analytical Technique

ISE

Details of Method

Analytical Characteristics

Direct potentiometric measurement by using an Ag/AgS/ISE

Oxidation of sulfide by dissolved O2 must be prevented and ionic strength must be adjusted. An alkaline antioxidant reagent (NaOH, ascorbic acid, and EDTA) is used for this purpose. Dissolved organic matter may interfere with Ag/AgS/ISE measurements.

Reference 50

Many of the UV-VIS spectrophotometric methods (shown in Tables 12.3 and 12.6) have been automated by using flow analyzers. Thus, nitrite and nitrate,50,82 ammonium,50,83 orthophosphate,50,84,85 silicates,50,86 chloride,50,87 cyanide,50,88 and sulfate50,89 are measured by CFA and FIA. Oxygen is measured by iodometric titration51,90 and electrochemical methods91 (Table 12.7). Other dissolved gasses (Table 12.2) are measured by ISE-based gas sensors. Finally, metals (Table 12.8) are determined by UV-VIS spectrophotometry51,92-97 and atomic spectrometry techniques.50,51,98-113 Other nonstandard methods (including CE and ASV) commonly used for determining inorganic constituents in water are summarized in selected monographs.114-117

TABLE 12.7 Selected Standard Methods for the Determination of Dissolved Gases Analyte O2

Analytical Technique

Details of Method

Analytical Characteristics

Reference

Iodometric titration

It is based on the addition of Mn2+ solution, followed by the addition of a strong alkali to the sample in a glass-stoppered bottle. Dissolved O2 rapidly oxidizes an equivalent amount of the dispersed divalent manganous hydroxide precipitate to hydroxides of higher valence states. In the presence of iodide ions in an acidic solution, the oxidized manganese reverts to the divalent state, with the liberation of a quantity of iodine equivalent to the original dissolved O2 content. The iodine is then titrated with a standard solution of thiosulfate. The titration end point can be detected visually with a starch indicator, or by potentiometric techniques. The liberated iodine can be determined colorimetrically.

Applicable to 0.2 mg–20 mg L . Oxidizing and reducing species interfere. To minimize interference, several modifications of the iodometric method are given (azide modification, permanganate modification, and the copper sulfate-sulfamic acid flocculation modification).

51,90

Dissolved oxygen meter

The O2 diffused through the membrane is reduced at the cathode: O2 + 4H3O+ + 4 e- ↔ 6H2O; the electrons originate from the anodic reaction: Ag + Cl- → AgCl(s) + e-.

Suitable for polluted and highly colored waters

91

-1

Analytical Technique

VIS

VIS

VIS

VIS

VIS

VIS

VIS

FAAS

FAAS

Analyte

Al

As

Cr(VI) and total Cr

Fe

Cr(VI)

Mn

Mn

Al

Cd

Details of Method

Arsenic in the sample is converted to arsine, which is evolved and then complexed with silver diethyldithiocarbamate. The intensity of the color of the complex is measured at 510–525 nm. Cr(VI) reacts with 1,5-diphenylcarbazide to form a colored complex, which is measured at 540 nm. For total chromium determination, Cr(III) is first oxidized to Cr(VI) by KMnO4. Iron (II) reacts with 1,10-phenanthroline to form a colored complex, which can be determined colorimetrically Cr(VI) reacts with diphenylcarbazide to form a colored complex, which is determined at 540 nm Manganese reacts with formaldoxime to form a colored complex, which can be determined colorimetrically Mn compounds react with ammonium persulfate/silver nitrate to form permanganate, which is determined at 525 nm Al is measured by aspirating the sample directly into the NO2/C2H2 flame and measuring the absorbance at 309.3 nm Cd is measured by aspirating the sample directly into the air/C2H2 flame and measuring the absorbance at 228.8 nm

Aluminum reacts with pyrocatechol violet to form a colored complex, which can be determined colorimetrically

TABLE 12.8 Selected Standard Methods for the Determination of Metals

Applicable to 5–100 mg L-1. SO42-, Cl-, PO43-, Na, K, Mg, Ca, Fe, Ni, Co, Cd, Pb, Si, Ti, and F may interfere. Applicable to 0.05–1.0 mg L-1. SO42-, Cl-, PO43-, Na, K, Mg, Ca, Fe, Ni, Co, Cd, Pb, Si, and Ti may interfere.

Applicable to 0.05–1.5 mg L-1 in natural and waste waters. Cl-, Br-, I-, and organic matter may interfere.

95

Specific procedure for water and waste water. The procedures are applicable to concentrations between 0.01 and 5 mg L-1. Applicable to 2.0–50 μg L-1 in slightly polluted tap, surface, and ground waters. S2-, Cl2, ClO2, O3, and H2O2 may interfere Applicable to concentrations between 0.01 and 5 mg L-1 in surface and drinking water

99

98

51

97

96

94

93

continued

Reference 92

Applicable to 0.005–0.2 mg L-1 in surface and waste waters. Hg, Fe, Mo, and V may interfere.

Applicable up to 100 μg L (50 mm cells) and up to 500 μg L-1 (10 mm cells) in potable waters, ground waters, and lightly polluted surface and sea waters Applicable to 0.001–0.1 mg L-1 in surface and waste waters. Interference from Sb may be important. Ag, Cr, Co, Mo, Ni, Hg, and Pt at concentrations <5 mg L-1 do not interfere.

-1

Analytical Characteristics

Analytical Techniques for the Determination of Inorganic Constituents 291

Analytical Technique

FAAS

FAAS

FAAS

FAAS

FAAS

FAAS

FAAS

Cr

K

Na

Ag, Au, Bi, Ca, Cd, Co, Cr, Cu, Fe, Ir, K, Li, Mg, Mn, Na, Ni, Pd, Pb, Pt, Rh, Ru, Sb, Sn, Sr, Tl, and Zn

Al, Ba, Be, Ca, Mo, Os, Re, Si, Th Ti, and V

Cd, Cr, Cu, Fe, Pb, Mg, Mn, Ag, and Zn

Co, Ni, Cu, Zn, Cd, and Pb

(continued)

Analyte

TABLE 12.8 Details of Method

K is measured by aspirating the sample directly into the air/C2H2 flame and measuring the absorbance at 766.5 nm Na is measured by aspirating the sample directly into the air/C2H2 flame and measuring the absorbance at 589.0 nm Metals are determined by FAAS: the sample is aspirated directly into the air/ C2H2 flame. Ag, Cd, Co, Cr, Cu, Fe, Mn, Ni, and Zn at low concentrations must be extracted prior to quantification Metals are determined by FAAS: the sample is aspirated directly into the NO2/C2H2 flame. Al and Be at low concentrations must be extracted prior to quantification. Metals are determined by FAAS; Pb and Cd at low concentrations are chelated (ammonium pyrrolidine dithiocarbamate at pH = 2.5), preconcentrated, and then extracted with methyl isobutyl ketone prior to quantification Metals are directly determined by FAAS; metals are determined after chelation with ammonium pyrrolidine dithiocarbamate and extraction in methyl isobutyl ketone; and metals are determined after chelation with hexamethyleneammonium– hexamethylenedithiocarbamate and extraction in di-isopropyl ketone-xylene

Cr is measured by aspirating the sample directly into the NO2/C2H2 flame and measuring the absorbance at 357.9 nm -

Reference

50

50

51

103

Applicable to natural waters

Applicable to surface and saline waters Ionization interferences are generally removed by the addition of LaCl3

Applicable to natural waters

51,102

50,101

100

Applicable to natural waters

Applicable to 5–50 mg L-1. Interference due to ionization is removed by the addition of CsCl

24

Applicable to 0.5–20 mg L . SO , Cl , Na, K, Mg, Ca, Fe, Ni, Co, Al, and Zn may interfere. Interference due to ionization is generally removed by the addition of LaCl3. Applicable to 5–50 mg L-1. Interference due to ionization is removed by the addition of CsCl

-1

Analytical Characteristics

292 Analytical Measurements in Aquatic Environments

Metals are measured by ICP-OES using the manufacturer’s recommended conditions Metals are measured by ICP-MS using the manufacturer’s recommended conditions

Organic Hg is oxidized to inorganic Hg by KMnO4, K2S2O8, and heating. The Hg is chemically reduced to the elemental state with stannous chloride or sodium tetrahydroborate; the vapor generated is transferred to the absorption cell and measured at 253.7 nm

ETAAS

ETAAS

ETAAS

ICP-OES

ICP-MS

CV-AAS

Cd

Cr

Ag, Al, As, Cd, Co, Cr, Cu, Fe, Mn, Mo, Ni, Pb, Sb, Se, Tl, V, and Zn

Ag, Al, As, B, Ba, Be, Bi, Ca, Cd, Co, Cr, Cu, Fe, K, Li, Mg, Mn, Mo, Na, Ni, P, Pb, S, Sb, Se, Si, Sn, Sr, Ti, V, W, Zn, and Zr Ag, Al, As, Au, B, Ba, Be, Bi, Ca, Cd, Ce, Co, Cr, Cs, Cu, Dy, Er, Eu, Fe, Ga, Gd, Ge, Hf, Ho, In, Ir, K, La, Li, Lu, Mg, Mn, Mo, Na, Nd, Ni, P, Pb, Pd, Pr, Pt, Rb, Re, Rh, Ru, S, Sb, Sc, Se, Si, Sm, Sn, Sr, Tb, Te, Th, Tl, Tm, Ti, U, V, W, Y, Yb, Zn, and Zr Hg

Cd is measured by ETAAS at 228.8 nm using an injection volume of 10 μL Cr is measured by ETAAS at 357.9 nm using an injection volume of 20 μL Metals are measured by ETAAS using the manufacturer’s recommended conditions and an injection volume of 20 μL

ETAAS

Al

Na and K are measured by aspirating the sample into a flame of sufficient thermal energy to cause the emission of characteristic radiation and measuring the intensity at 589.0 and 766.5 nm for Na and K, respectively Al is measured by ETAAS at 309.3 nm using an injection volume of 20 μL

FAES

Na and K

Applicable to 0.1–10 μg L-1 in surface, ground, and waste waters

Applicable to 0.1–1.0 μg L-1 in tap, surface, ground, and waste water

Applicable to tap and waste water

Applicable to 10–100 μg L-1. Fe, Cu, Ni, Co, Cd, Pb, Si, Na, K, Ca, Cl-, SO42-, PO43-, and acetate may interfere. Applicable to 0.3–3.0 μg L-1. Fe, Cu, Ni, Co, Pb, Na, K, Ca, Mg, Cl-, and SO42- may interfere. Applicable to 5.0–100 μg L-1. SO42-, Cl-, Na, K, Mg, Ca, Fe, Ni, Co, Al, and Zn may interfere. Applicable to surface, ground, tap, and waste water. A high Cl- concentration interferes. To minimize the matrix effect, the chemical modification, standard addition method, and background correction systems may be used.

Applicable to water samples with Na and K concentrations up to 10 mg L-1

continued

51,109

50,107,108

50,106

105

100

99

98

104

Analytical Techniques for the Determination of Inorganic Constituents 293

Analytical Technique

CV-AAS (amalgamation)

CV-AFS

HG-AAS

HG-AAS

Hg

Hg

As

Se

(continued)

Analyte

TABLE 12.8 Hg is chemically reduced to the elemental state with stannous chloride or sodium tetrahydroborate; the vapor generated is collected on an amalgamation surface/ Au or Pt. The concentrated mercury is revolatilized by rapid heating of the amalgamation surface and transferred to the absorption cell for measurement at 253.7 nm Hg is chemically reduced to the elemental state with stannous chloride; the vapor generated is transferred and measured by AFS As is chemically reduced to arsine with sodium tetrahydroborate; the vapor generated is transferred to the absorption cell and measured at 193.7 nm Se(IV) is chemically reduced to selenium hydride with sodium tetrahydroborate; the vapor generated is transferred to the absorption cell and measured at 196.0 nm

Details of Method

50,112

50,113

Applicable to selenium and organic selenium in drinking, ground, and surface waters, in a concentration range of 1–10 μg L-1. To avoid errors in determination, other oxidation states need to be converted to Se(IV) prior to the determination

111

110

Reference

Applicable to 1.0–10 μg L-1 in tap, surface, and ground waters

Applicable to 0.001–10 μg L-1 in tap, rain, surface, ground, and waste waters

Applicable to 0.1–1.0 μg L in surface, ground, and waste waters

-1

Analytical Characteristics

294 Analytical Measurements in Aquatic Environments

Analytical Techniques for the Determination of Inorganic Constituents

295

ACRONYMS AND ABBREVIATIONS AAS AES AFS ASV CCD CE CFA CGE CID CIEF CITP CS CSV CV-AAS CV-AFS CVG CVG-AAS CVG-AFS CVG-ICP-MS CVG-ICP-OES CV-ICP-MS CV-ICP-OES CZE DC DME EcHG EDL EOF ETAAS FAAS FAES FIA HCL HG-AAS HG-AFS HG-ICP-MS HG-ICP-OES HI-HCL HPLC HR-CS AAS IC ICP ICP-MS ICP-OES ISE ISO LEAFS LIF

atomic absorption spectrometry atomic emission spectrometry atomic fluorescence spectrometry anodic stripping voltammetry charge-coupled device capillary electrophoresis continuous flow analysis capillary gel electrophoresis charge injection device capillary isoelectric focusing capillary isotachophoresis continuous source cathodic stripping voltammetry cold vapor-atomic absorption spectrometry cold vapor-atomic fluorescence spectrometry chemical vapor generation chemical vapor generation-atomic absorption spectrometry chemical vapor generation-atomic fluorescence spectrometry chemical vapor generation-inductively coupled plasma-mass spectrometry chemical vapor generation-inductively coupled plasma-optical emission spectrometry cold vapor-inductively coupled plasma-mass spectrometry cold vapor-inductively coupled plasma-optical emission spectrometry capillary zone electrophoresis direct current dropping mercury electrode electrochemical hydride generation electrodeless discharged lamp electro-osmotic flow electrothermal atomic absorption spectrometry flame atomic absorption spectrometry flame atomic emission spectrometry flow injection analysis hollow cathode lamp hydride generation-atomic absorption spectrometry hydride generation-atomic fluorescence spectrometry hydride generation-inductively coupled plasma-mass spectrometry hydride generation-inductively coupled plasma-optical emission spectrometry high intensity-hollow cathode lamp high-performance liquid chromatography high resolution-continuous source atomic absorption spectrometry ion chromatography inductively coupled plasma inductively coupled plasma-mass spectrometry inductively coupled plasma-optical emission spectrometry ion-selective electrode International Organization for Standardization laser-excited atomic fluorescence spectrometry laser-induced atomic fluorescence spectrometry

296

LS MEKC OES PTFE RF SFA SPME STAT STPF THGA TOF UV VIS WCAT

Analytical Measurements in Aquatic Environments

line source micellar electrokinetic chromatography optical emission spectrometry polytetrafluoroethylene radio frequency segmented-flow analysis solid-phase microextraction slotted tube atom trap stabilized temperature platform furnace transversal heated graphite atomizer time of flight ultraviolet visible water-cooled atom trap

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20. Montaser, A. and D.W. Golightly (eds). 1998. Inductively Coupled Plasmas in Analytical Atomic Spectrometry. New York, USA: VCH. 21. Nölte, J. 2003. ICP Emission Spectrometry. A Practical Guide. Weinheim, Germany: Wiley-VCH Verlag. 22. Dean, J.R. 2005. Practical Inductively Coupled Plasma Spectroscopy. Hoboken, NJ: Wiley. 23. Todolí, J.L. and J.M. Mermet. 2005. Elemental analysis of liquid microsamples through inductively coupled plasma spectrochemistry. Trends Anal. Chem. 24: 107–116. 24. Maestre, S.E., J.L. Todolí, and J.M. Mermet. 2004. Evaluation of several pneumatic micronebulizers with different designs for use in ICP-AES and ICP-MS. Future directions for further improvements. Anal. Bioanal. Chem. 379: 888–899. 25. Almagro, B., A.M. Ganan-Calvo, M. Hidalgo, and A. Canals. 2006. Flow focusing pneumatic nebulizers in comparison with several micronebulizers in inductively coupled plasma atomic emission spectrometry. J. Anal. At. Spectrom. 21: 770–777. 26. McLaughlin, R.L.J. and I.D. Brindle. 2005. Multimode Sample Introduction System. United States Patent US 6,891,605 B2, May 10, 2005. 27. Lowe, R.M. 1971. High-intensity hollow-cathode lamp for atomic fluorescence. Spectrochim. Acta B 26: 201–205. 28. Broekaert, J.A.C. 2005. Analytical Atomic Spectrometry with Flames and Plasmas, 2nd edition. Weinheim, Germany: Wiley-VCH Verlag. 29. Jarvis, K.E., A.L. Gray, and R.S. Houk. 1996. Handbook of Inductively Coupled Plasma Mass Spectrometry. London, UK: Blackie Academic & Professional. 30. Hill, S.J. (ed.). 2007. Inductively Coupled Plasma Spectrometry and its Applications, 2nd edition. Oxford, UK: Blackwell Publishing Ltd. 31. Sabe, R. and G. Rauret. 2004. Challenges for achieving traceability of analytical measurements of heavy metals in environmental samples by isotopic dilution mass spectrometry. Trends Anal. Chem. 23: 273–280. 32. Deˇdina J. and D.L. Tsalev. 1995. Hydride Generation Atomic Absorption Spectrometry. Surrey, UK: Wiley. 33. Sturgeon, R.E., X. Guo, and Z. Mester. 2005. Chemical vapor generation: Are further advances yet possible? Anal. Bioanal. Chem. 382: 881–883. 34. Pohl, P. 2004. Recent advances in chemical vapor generation via reaction with sodium tetrahydroborate. Trends Anal. Chem. 23: 21–27. 35. Pohl, P. 2004. Hydride generation—recent advances in atomic emission spectrometry. Trends Anal. Chem. 23: 87–101. 36. D’Ulivo, A. 2004. Chemical vapor generation by tetrahydroborate (III) and other borane complexes in aqueous media—A critical discussion of fundamental processes and mechanisms involved in reagent decomposition and hydride formation. Spectrochim. Acta B 59: 793–825. 37. Narsito, J. Agterdenbos, and S.J. Santosa. 1990. Study of processes in the hydride generation atomic absorption spectrometry of antimony, arsenic and selenium. Anal. Chim. Acta 237: 189–199. 38. Laborda, F., E. Bolea, and J.R. Castillo. 2007. Electrochemical hydride generation as a sample introduction technique in atomic spectrometry: Fundamentals, interferences and applications. Anal. Bioanal. Chem. 388: 743–775. 39. Tsalev, D.L. 2000. Vapor generation or electrothermal atomic absorption spectrometry? Both! Spectrochim. Acta B 55: 917–933. 40. Chaudhry, M.M., A.M. Ure, B.G. Cooksey, D. Littlejohn, and D.J. Halls. 1991. Investigation of in situ concentration of hydride forming elements in a graphite furnace atomizer. Anal. Proc. 28: 44–46. 41. Bard, A.J. and L.R. Faulkner. 2001. Electrochemical Methods. Fundamentals and Applications. New York: Wiley. 42. Wang J. 1985. Stripping Analysis. Principles, Instrumentation and Applications. Weinheim, Germany: VCH. 43. Brainina, Kh. and E. Neyman. 1993. Electroanalytical Stripping Methods. New York: Wiley. 44. Evans, A. 1987. Potentiometry and Ion Selective Electrodes. New York:Wiley. 45. Lough, W.J. 1995. High Performance Liquid Chromatography. Principles and Practice. London: Blackie Academic & Professional. 46. Meyer, V. 1994. Practical High Performance Liquid Chromatography. New York: Wiley. 47. Morteza, K. 1998. High-Performance Capillary Electrophoresis. Theory, technique, and applications. New York: Wiley.

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48. Shintani, H. and J. Polonsky. 1997. Handbook of Capillary Electrophoresis Applications. London: Blackie Academic & Professional. 49. Valcárcel, M. and M.D. Luque de Castro. 1988. Automatic Methods of Analysis. Amsterdam: Elsevier. 50. APHA. 1998. Standard Methods for the Examination of Water and Wastewater, 20th edition. American Public Health Association (APHA), American Water Works Association (AWWA), Water Environment Federation publication (WPCF). APHA, Washington, DC. 51. Official methods of analysis of The Association of Official Analytical Chemists. 2005. Methods Manual, 18th Edition. 52. International Standard Organization. 1984. Water quality. Determination of nitrite. Molecular absorption spectrometric method. ISO 6777. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 53. Standing Committee of Analysis. 1981. Methods for Examination of Waters and Associated Materials— Ammonia in Water. London: Her Majesty’s Stationery Office. 54. U.S. Environmental Protection Agency. 1991. Methods for Chemical Analysis of Water and Wastes. Washington, DC: United States Environmental Protection Agency, Office of Research and Development. 55. International Standard Organization. 1984. Water quality. Determination of ammonium nitrogen. Distillation and titrimetric method. ISO 5664. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 56. International Standard Organization. 1984. Water quality. Determination of ammonium. Potentiometric method. ISO 6778. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 57. International Standard Organization. 1984. Water quality. Determination of Kjeldahl nitrogen. Method after mineralization with selenium. ISO 5663. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 58. International Standard Organization. 1997. Water quality. Determination of nitrogen. Part 1: Method using oxidative digestion with peroxodisulfate. ISO 11905-1. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 59. International Standard Organization. 2004. Water quality. Determination of phosphorus. Ammonium molybdate spectrometric method. ISO 6878. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 60. USEPA. 1994. Methods for the Determination of Metals in Environmental Samples Supplement I. EPA 600/R 94/111. 61. ASTM Standard. 1997. D4327/97 Standard Test Method for Anions in Water by Chemically suppressed Ion Chromatography. 62. International Standard Organization. 2007. Water quality. Determination of dissolved anions by liquid chromatography of ions. Part 1: Determination of bromide, chloride, fluoride, nitrate, nitrite, phosphate and sulfate. ISO 10304-1. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 63. International Standard Organization. 1995. Water quality. Determination of dissolved anions by liquid chromatography of ions. Part 2: Determination of bromide, chloride, nitrate, nitrite, orthophosphate and sulfate in waste water. ISO 10304-2. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 64. International Standard Organization. 1998. Water quality. Determination of dissolved Li+, Na+, NH4+, K+, Mn2+, Ca2+, Mg2+, Sr2+ and Ba2+ using ion chromatography. Method for water and waste water. ISO 14911. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 65. International Standard Organization. 1997. Water quality. Determination of dissolved anions by liquid chromatography of ions. Part 3: Determination of chromate, iodide, sulfite, thiocyanate and thiosulfate. ISO 10304-3. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 66. International Standard Organization. 1997. Water quality. Determination of dissolved anions by liquid chromatography of ions. Part 4: Determination of chlorate, chloride and chlorite in water with low contamination. ISO 10304-4. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 67. International Standard Organization. 1994. Water quality. Determination of alkalinity. Part 1: Determination of total and composite alkalinity. ISO 9963-1. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland.

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68. International Standard Organization. 1994. Water quality. Determination of alkalinity. Part 2: Determination of carbonate alkalinity. ISO 9963-2. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 69. International Standard Organization. 2008. Water quality. Determination of total alkalinity in sea water using high precision potentiometric titration. ISO 22719. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 70. International Standard Organization. 1984. Water quality. Determination of calcium content. EDTA titrimetric method. ISO 6058. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 71. International Standard Organization. 1984. Water quality. Determination of the sum of calcium and magnesium. EDTA titrimetric method. ISO 6059. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 72. International Standard Organization. 1986. Water quality. Determination of calcium and magnesium. Atomic absorption spectrometric method. ISO 7980. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 73. International Standard Organization. 1989. Water quality. Determination of chloride. Silver nitrate titration with chromate indicator (Mohr’s method). ISO 9297. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 74. 705 ASTM. 1971. Annual book of ASTM Standards. Part 23. Philadelphia, American Society for Testing and Materials. 75. International Standard Organization. 1985. Water quality. Determination of free chlorine and total chlorine. Part 1: Titrimetric method using N,N-diethyl-1,4-phenylenediamine. ISO 7393-1. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 76. International Standard Organization. 1985. Water quality. Determination of free chlorine and total chlorine. Part 2: Colorimetric method using N,N-diethyl-1,4-phenylenediamine, for routine control purposes. ISO 7393-2. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 77. International Standard Organization. 1990. Water quality. Determination of free chlorine and total chlorine. Part 3: Iodometric titration method for the determination of total chlorine. ISO 7393-3. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 78. International Standard Organization. 1992. Water quality. Determination of fluoride. Part 1: Electrochemical probe method for potable and lightly polluted water. ISO 10359-1. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 79. International Standard Organization. 1994. Water quality. Determination of fluoride. Part 2: Determination of inorganically bound total fluoride after digestion and distillation. ISO 10359-2. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 80. International Standard Organization. 1984. Water quality. Determination of cyanide. Part 1: Determination of total cyanide. ISO 6703-1. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 81. International Standard Organization. 1984. Water quality. Determination of cyanide. Part 2: Determination of easily liberatable cyanide. ISO 6703-2. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 82. International Standard Organization. 1996. Water quality. Determination of nitrite nitrogen and nitrate nitrogen and the sum of both by flow analysis (CFA and FIA) and spectrometric detection. ISO 13395. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 83. International Standard Organization. 2005. Water quality. Determination of ammonium nitrogen. Method by flow analysis (CFA and FIA) and spectrometric detection. ISO 11732. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 84. International Standard Organization. 2003. Water quality. Determination of orthophosphate and total phosphorus contents by flow analysis (FIA and CFA). Part 1: Method by flow injection analysis (FIA). ISO 15681-1. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 85. International Standard Organization. 2003. Water quality. Determination of orthophosphate and total phosphorus contents by flow analysis (FIA and CFA). Part 2: Method by continuous flow analysis (CFA). ISO 15681-2. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland.

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Analytical Measurements in Aquatic Environments

86. International Standard Organization. 2002. Water quality. Determination of soluble silicates by flow analysis (FIA and CFA) and photometric detection. ISO 16264. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 87. International Standard Organization. 2000. Water quality. Determination of chloride by flow analysis (CFA and FIA) and photometric or potentiometric detection. ISO 15682. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 88. International Standard Organization. 2002. Water quality. Determination of total cyanide and free cyanide by continuous flow analysis. ISO 14403. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 89. International Standard Organization. 2006. Water quality. Determination of sulfate. Method by continuous flow analysis (CFA). ISO 22743. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 90. International Standard Organization. 1983. Water quality. Determination of dissolved oxygen. Iodometric method. ISO 5813. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 91. International Standard Organization. 1990. Water quality. Determination of dissolved oxygen. Electrochemical probe method. ISO 5814. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 92. International Standard Organization. 1994. Water quality. Determination of aluminium. Spectrometric method using pyrocatechol violet. ISO 10566. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 93. International Standard Organization. 1982. Water quality. Determination of total arsenic. Silver diethyldithiocarbamate spectrophotometric method. ISO 6595. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 94. International Standard Organization. 1994. Water quality. Determination of chromium(VI). Spectrometric method using 1,5-diphenylcarbazide. ISO 11083. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 95. International Standard Organization. 1988. Water quality. Determination of iron. Spectrometric method using 1, 10-phenanthroline. ISO 6332. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 96. International Standard Organization. 2005. Water quality. Determination of chromium(VI). Photometric method for weakly contaminated water. ISO 18412. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 97. International Standard Organization. 1986. Water quality. Determination of manganese. Formaldoxime spectrometric method. ISO 6333. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 98. International Standard Organization. 1997. Water quality. Determination of aluminium. Atomic absorption spectrometric methods. ISO 12020. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 99. International Standard Organization. 1994. Water quality. Determination of cadmium by atomic absorption spectrometry. ISO 5961. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 100. European Standard. 1996. Water quality. Determination of chromium. Atomic absorption spectrometric methods. EN 1233. European Committee for Standardization, Brussels, Belgium. 101. International Standard Organization. 1993. Water quality. Determination of sodium and potassium. Part 2: Determination of potassium by atomic absorption spectrometry. ISO 9964-2. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 102. International Standard Organization. 1993. Water quality. Determination of sodium and potassium. Part 1: Determination of sodium by atomic absorption spectrometry. ISO 9964-1. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 103. International Standard Organization. 1986. Water quality. Determination of cobalt, nickel, copper, zinc, cadmium and lead. Flame atomic absorption spectrometric methods. ISO 8288. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 104. International Standard Organization. 1993. Water quality. Determination of sodium and potassium. Part 3: Determination of sodium and potassium by flame emission spectrometry. ISO 9964-3. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland.

Analytical Techniques for the Determination of Inorganic Constituents

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105. International Standard Organization. 2003. Water quality. Determination of trace elements using atomic absorption spectrometry with graphite furnace. ISO 15586. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 106. International Standard Organization. 2007. Water quality. Determination of selected elements by inductively coupled plasma optical emission spectroscopy (ICP-OES). ISO 11885. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 107. International Standard Organization. 2004. Water quality. Application of inductively coupled plasma mass spectrometry (ICP-MS). Part 1: General guidelines. ISO 17294-1. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 108. International Standard Organization. 2003. Water quality. Application of inductively coupled plasma mass spectrometry (ICP-MS). Part 2: Determination of 62 elements. ISO 17294-2. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 109. European Standard. 2007. Water quality. Determination of mercury. Method using atomic absorption spectrometry. EN 1483. European Committee for Standardization, Brussels, Belgium. 110. European Standard. 1998. Water quality. Determination of mercury. Enrichment methods by amalgamation. EN 12338. European Committee for Standardization, Brussels, Belgium. 111. European Standard. 2001. Water quality. Determination of mercury by atomic fluorescence spectrometry. EN 13506. European Committee for Standardization, Brussels, Belgium. 112. International Standard Organization. 1996. Water quality. Determination of arsenic. Atomic absorption spectrometric method (hydride technique). ISO 11969. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 113. International Standard Organization. 1993. Water quality. Determination of selenium. Atomic absorption spectrometric method (hydride technique). ISO 9965. International Organization for Standardization, Case Postale 56, CH-1211, Geneva 20 Switzerland. 114. Burden F.R., I. McKelvie, U. Förstner, and A. Guenther. 2002. Environmental Monitoring Handbook. New York: McGraw-Hill. 115. Nollet, L.M.L. 2000. Handbook of Water Analysis. New York: Marcel Dekker. 116. Dean, J.R. 2003. Methods for Environmental Trace Analysis. New York: Wiley. 117. Quevauviller, P. and K.C. Thompson. 2006. Analytical Methods for Drinking Water. Advances in Sampling and Analysis. New York: Wiley.

13

Analytical Techniques for the Determination of Organic and Organometallic Analytes Erwin Rosenberg

CONTENTS 13.1 Introduction ...................................................................................................................... 13.1.1 Water as a Matrix for Organic and Organometallic Analytes .............................. 13.1.2 The Human Impact on the Hydrosphere .............................................................. 13.1.3 Classification of Organic and Organometallic Pollutants .................................... 13.2 Analytical Methods .......................................................................................................... 13.2.1 Classification ......................................................................................................... 13.2.2 Separation Techniques .......................................................................................... 13.2.2.1 Gas Chromatography ............................................................................. 13.2.2.2 Liquid Chromatography ......................................................................... 13.2.2.3 Capillary Electrophoresis ...................................................................... 13.2.2.4 Other Separation Techniques ................................................................. 13.2.2.5 Size Exclusion Chromatography ............................................................ 13.2.3 Detection Techniques ........................................................................................... 13.2.3.1 Quadrupole Mass Spectrometers ........................................................... 13.2.3.2 Ion Trap Mass Spectrometers ................................................................ 13.2.3.3 Triple Quadrupole Mass Spectrometers ................................................ 13.2.3.4 Time-of-Flight (TOF) Instruments ........................................................ 13.2.3.5 Fourier-Transform Ion Cyclotron Resonance Instruments .................... 13.2.3.6 Ionization Techniques ............................................................................ 13.2.3.7 Inductively Coupled Plasma-Mass Spectrometry .................................. 13.2.4 Sample Preparation for Chromatographic Analysis ............................................. 13.2.5 Analyte Derivatization .......................................................................................... 13.2.6 Nonchromatographic Techniques ......................................................................... 13.3 Applications to Different Classes of Pollutants ................................................................ 13.3.1 Solvents and Volatile Compounds ........................................................................ 13.3.2 Pesticides .............................................................................................................. 13.3.3 Phenols and Other Industrial Contaminants ......................................................... 13.3.4 Surfactants ............................................................................................................ 13.3.5 Sulfonates ............................................................................................................. 13.3.6 Estrogenic Substances .......................................................................................... 13.3.7 Pharmaceuticals .................................................................................................... 13.3.8 Personal Care and Cosmetic Products (PCCPs) ...................................................

304 304 305 305 306 306 309 309 311 313 315 315 315 316 316 316 317 317 317 318 318 325 326 329 329 330 330 331 333 333 334 334

303

304

Analytical Measurements in Aquatic Environments

13.3.9 Organometallic Species ........................................................................................ 13.3.9.1 Organotin (OT) Compounds .................................................................. 13.3.9.2 Organolead Compounds ........................................................................ 13.3.9.3 Organogermanium Compounds ............................................................. 13.3.9.4 Organoselenium Compounds ................................................................. 13.4 Conclusions and Outlook .................................................................................................. References ..................................................................................................................................

13.1 13.1.1

335 335 339 339 340 342 342

INTRODUCTION WATER AS A MATRIX FOR ORGANIC AND ORGANOMETALLIC ANALYTES

Water covers almost three-quarters of the surface of our planet and is the most valuable resource for humans, fauna, and flora. However, only 0.65% of the water masses of our planet are fresh water and they are subject to severe environmental pressures. It is therefore to be expected that, without appropriate counteraction, about 2/3 of the world’s population will be deprived of access to fresh water by 2025.1 Water plays various roles in our lives and environment: rivers, lakes, and oceans provide important transportation routes; water is essential in industry (as a solvent) and in agriculture (for irrigation in intensive farming); water serves as a habitat for flora and fauna; and most importantly, water is an essential foodstuff that is consumed in large quantities. For all these reasons, the maintenance of water quality is of the utmost importance, and the monitoring of water quality is a task that requires powerful analytical methods. Only rarely, for example, in the case of accidental release, do concentration levels of organic and organometallic contaminants in water samples reach or exceed the ppm level at which some analytes may already exhibit acute toxicity. Nonetheless, chronic effects are observed already at concentrations that are typically three orders of magnitude lower. Moreover, since some analytes are known to be carcinogenic or to exhibit endocrine disrupting effects, organic and organometallic contaminants have to be monitored at the low and sub-ppb level in the hydrosphere. This calls for the development and application of sophisticated analytical methods. This chapter discusses the analytical strategies for determining organic and organometallic pollutants at these low concentration levels. It will cover the analysis of organic and organometallic pollutants exclusively in the aqueous (truly dissolved) phase; while analyses applicable to the colloidal phase, sediments, and biota are dealt with in dedicated reviews.2-4 We shall therefore discuss the analysis of organic and organometallic pollutants at the different stages of the water cycle, including pristine (spring and river) water, ocean water, ground water, waste water, rain, and fog water (Figure 13.1). The justification for treating organic and (selected) organometallic contaminants

Surface water River water Riverbank filtrate

Evaporation Waste water treatment plant

Rain and Precipitation Dam

Water works

Spring Ground water

FIGURE 13.1

Wells

Biogeochemical cycle of water and possible threats to water quality.

Analytical Techniques for the Determination of Organic and Organometallic Analytes

305

in the same chapter is that the methods of analysis and the instrumentation used for this task are essentially the same for both groups of compounds.

13.1.2

THE HUMAN IMPACT ON THE HYDROSPHERE

The intensive use of water in its different functions exposes this resource to human impacts of various kinds. Industrial use leads to the discharge of industrial pollutants, mostly from point sources of high intensity: typical examples are solvents, intermediates, and other process chemicals. In contrast to this, the household use of water leads to widespread contamination at low concentrations. The probably most important group of compounds in this context is that of personal care and cosmetic products (PCCPs), which are practically in ubiquitous use, and enter water bodies despite having passed through communal waste water treatment plants (WWTPs). Agriculture has a further important impact on water quality: (inorganic) fertilizers and organic pesticides (mostly herbicides, insecticides, and fungicides) are used in large quantities in intensive farming, and antibiotics in cattle breeding. Transportation is the third major source releasing organic (various hydrocarbons) and organometallic compounds into the hydrosphere. When discussing these impacts and the analytical methods for the determination of analytes with such widely varying properties, it must be borne in mind that water bodies act not only as large reservoirs but also as reactors: The euphotic (well-illuminated) zone, typically representing the top few meters (depending on the content of particulate matter and sunlight intensity) of the water column, is the zone where photochemical reactions take place. Throughout the water column, organic and organometallic compounds may be transformed as a result of biological activity, photolysis, or hydrolysis, and in the anoxic zones of the sediments, reductive reactions may take place (Figure 13.2). All these processes lead to an increase in the complexity of water samples: these contain not only parent compounds, but also their metabolites, formed in the different types of reaction taking place in different zones of the water column.

13.1.3

CLASSIFICATION OF ORGANIC AND ORGANOMETALLIC POLLUTANTS

From the analytical point of view, it is appropriate to classify organic and organometallic compounds according to their physicochemical properties, as it is these that determine the analytical approach to be taken. The main criteria are volatility and polarity, although these factors are not completely independent. While polar compounds typically exhibit low to very low volatility,

FIGURE 13.2 Interactions of organic and organometallic pollutants in different zones of an aquatic ecosystem.

306

Low

Molecular weight

ca ri n (u dus ns tr p e ial c i ch fie e d) mi

th e

Personal care and cosmetic products (PCCP)

ls

Sulfonates Household and industrial detergents: Non-ionic/ionic detergents: APEO

O

Ionic Fully alkylated

Low

Volatile organic compounds, solvents

Organometallic compounds

Polarity

Pesticides

Pesticide metabolites

High

Analytical Measurements in Aquatic Environments

High

FIGURE 13.3 Common organic and organometallic pollutants in aquatic systems, classified according to the criteria of molecule size and polarity.

nonpolar organic and organometallic compounds are typically more volatile, as long as their molecular weight does not become too large (Figure 13.3). In the case of polar analytes, derivatization is a tool frequently used to increase volatility and thermal stability, and also to make them amenable to gas chromatographic separation.5-7 The so-called blacklists of compounds compiled by legislators for water quality monitoring in Europe or the United States, such as the one contained in the European Water Framework Directive,8 do not follow such rational criteria of classification. Instead, such “blacklists” (derived from a combination of toxicological considerations and the scale on which these compounds are produced and discharged into the environment) appear to have been drawn up quite arbitrarily, specifying as they do both explicitly named individual compounds as well as classes of generic compounds (Table 13.1). This heterogeneous range of compounds requires a battery of different analytical techniques that will be described in the following pages. As a starting point, readers may also refer to the database on analytical methods established as part of the European “Metropolis” project (in 2002–2004), which provides a web interface for seeking out analytical methods for individual analytes and sample matrices.9

13.2 13.2.1

ANALYTICAL METHODS CLASSIFICATION

Chromatographic and hyphenated techniques are the most important analytical methods used for analyzing organic and organometallic pollutants in water. This is in distinct contrast to the analysis of trace metals and inorganic (anionic) analytes, where, in the majority of cases, spectroscopic techniques are used. The reason for this is that in inorganic analysis, knowledge of the total element concentration may already provide sufficient indication of the contamination of a water body by a particular pollutant. In organic and speciation analytics, however, this is far from being sufficient, the only exception being parameters that have been defined by legislators as sum parameters for the assessment of water quality, such as adsorbable/extractable/purgeable organohalogen compounds (AOX/EOX/POX)10-13 or the phenol index.14 In all other cases, it is essential to correctly identify and quantitate the individual analytes present in order to assess the relevance of organic contaminants, and this inevitably requires efficient separation of the analytes from one another, and from the matrix

Analytical Techniques for the Determination of Organic and Organometallic Analytes

307

TABLE 13.1 Provisional Environmental Quality Standards (EQSs) as Proposed in the Common Position Adopted by the Council on December 20, 2007, with a View to the Adoption of a Directive of the European Parliament and of the Council on EQSs in the Field of Water Policy and Amending Directives 82/176/EEC, 83/513/EEC, 84/156/EEC, 84/491/EEC, 86/280/EEC, and 2000/60/EC

Number

Name of Substance

EQS-AAa EQS-AAa EQS-MACc EQS-MACc Inland Surface Other Surface Inland Surface Other Surface CAS-Number Watersb Waters Watersb Waters

1. 2. 3. 4. 5. 6.

Alachlor Anthracene Atrazine Benzene Brominated diphenyletherd Cadmium and its compounds (depending on water hardness classes)e

15972-60-8 120-12-7 1912-24-9 71-43-2 32534-81-9 7440-43-9

6a. 7. 8. 9.

Carbon tetrachloridef C10–C13 Chloroalkanes Chlorfenvinphos Chlorpyrifos (Chlorpyrifos-ethyl) Aldrinf Dieldrinf Isodrinf Endrinf DDT totalf,g Para–para-DDTf 1,2-Dichloroethane Dichloromethane Di(2-ethylhexyl)phthalate (DEHP) Diuron Endosulfan Fluoranthene Hexachlorobenzene Hexachlorobutadiene Hexachlorocyclohexane Isoproturon Lead and its compounds Mercury and its compounds Naphthalene Nickel and its compounds Nonylphenol (4-nonylphenol)

56-23-5 85535-84-8 470-90-6 2921-88-2

9a.

9b. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25.

0.3 0.1 0.6 8 0.0002 £ 0.08 (Class 1) 0.2 0.08 (Class 2) 0.09 (Class 3) 0.15 (Class 4) 0.25 (Class 5) 12 12 0.4 0.4 0.1 0.1 0.03 0.03

0.7 0.4 2.0 50 Not applicable

0.7 0.4 2.0 50 Not applicable

£ 0.45 (Class 1) 0.45 (Class 2) 0.6 (Class 3) 0.9 (Class 4) 1.5 (Class 5) Not applicable 1.4 0.3 0.1

Not applicable 1.4 0.3 0.1

309-00-2 60-57-1 465-73-6 72-20-8 Not applicable 50-29-3 107-06-2 75-09-2 117-81-7

S = 0.01

S = 0.005

Not applicable

Not applicable

0.025 0.01 10 20 1.3

0.025 0.01 10 20 1.3

Not applicable Not applicable Not applicable Not applicable Not applicable

Not applicable Not applicable Not applicable Not applicable Not applicable

330-54-1 115-29-7 206-44-0 118-74-1 87-68-3 608-73-1 34123-59-6 7439-92-1 7439-97-6 91-20-3 7440-02-0 104-40-5

0.2 0.005 0.1 0.01 0.1h 0.02h 0.3 7.2 0.05h 2.4 20 0.3

0.2 0.0005 0.1 0.01 0.1h 0.002h 0.3 7.2 0.05h 1.2 20 0.3

1.8 0.01 1 0.05 0.6 0.04 1.0 Not applicable 0.07 Not applicable Not applicable 2.0

1.8 0.004 1 0.05 0.6 0.02 1.0 Not applicable 0.07 Not applicable Not applicable 2.0

0.1

0.01

Not applicable

Not applicable

Octylphenol [(4-(1,1¢,3,3¢- 140-66-9 tetramethylbutyl)-phenol)]

0.3 0.1 0.6 10 0.0005

continued

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Analytical Measurements in Aquatic Environments

TABLE 13.1

Number 26. 27. 28.

29. 29a. 29b. 30. 31. 32. 33.

(continued)

Name of Substance

EQS-AAa EQS-AAa EQS-MACc EQS-MACc Inland Surface Other Surface Inland Surface Other Surface CAS-Number Watersb Waters Watersb Waters

Pentachlorobenzene Pentachlorophenol Polyaromatic hydrocarbons (PAHs)i Benzo(a)pyrene Benzo(b)fluoranthene

608-93-5 87-86-5 Not applicable

0.007 0.4 Not applicable

0.0007 Not applicable 0.4 1 Not applicable Not applicable

Not applicable 1 Not applicable

50-32-8 205-99-2

0.05

0.05

0.1

0.1

S = 0.03

S = 0.03

Benzo(k)fluoranthene Benzo(g,h,i)perylene

207-08-9 191-24-2

S = 0.002

S = 0.002

Not applicable

Not applicable

Indeno(1,2,3-cd)pyrene Simazine Tetrachloroethylenef Trichloroethylenef Tributyltin compounds (tributyltin cation) Trichlorobenzenes Trichloromethane Trifluralin

193-39-5 122-34-9 127-18-4 79-01-6 36643-28-4

1 10 10 0.0002

1 10 10 0.0002

4 Not applicable Not applicable 0.0015

4 Not applicable Not applicable 0.0015

12002-48-1 67-66-3 1582-09-8

0.4 2.5 0.03

0.4 2.5 0.03

Not applicable Not applicable Not applicable

Not applicable Not applicable Not applicable

Source: Adapted from Lepom, P. et al. 2009. J. Chromatogr. A. 1216: 302–315. Note: Concentrations are given in mg/L. AA, annual average; CAS, chemical abstracts service; MAC, maximum allowable concentration. a This parameter is the EQS expressed as an annual average value (AA-EQS). Unless otherwise specified, it applies to the total concentration of all isomers. b Inland surface waters encompass rivers and lakes and related artificial or heavily modified water bodies. c This parameter is the EQS expressed as a maximum allowable concentration (MAC-EQS). Where the MAC-EQSs are marked as “not applicable,” the AA-EQS values are considered protective against short-term pollution peaks in continuous discharges since they are significantly lower than the values derived on the basis of acute toxicity. d For the group of priority substances covered by brominated diphenyl ethers (No. 5) listed in Decision 2455/2001/EC, an EQS is established only for congener numbers 28, 47, 99, 100, 153, and 154. e For cadmium and its compounds (No. 6), the EQS values vary depending upon the hardness of the water as specified in five class categories (Class 1: <40 mg CaCO3 L-1, Class 2: 40 to <50 mg CaCO3 L-1, Class 3: 50 to <100 mg CaCO3 L-1, Class 4: 100 to <200 mg CaCO3 L-1, and Class 5: ≥200 mg CaCO3 L-1). f This substance is not a priority substance but one of the other pollutants for which the EQSs are identical to those laid down in the legislation that applied prior to the entry into force of this Directive. g DDT total comprises the sum of the isomers 1,1,1-trichloro-2,2 bis(p-chlorophenyl)ethane (CAS number 50-29-3; EU number 200-024-3); 1,1,1-trichloro-2 (o-chlorophenyl)-2-(p-chlorophenyl)ethane (CAS number 789-02-6; EU number 212-332-5); 1,1-dichloro-2,2 bis(p-chlorophenyl)ethylene (CAS number 72-55-9; EU number 200-784-6); and 1,1-dichloro-2,2 bis(p-chlorophenyl)ethane (CAS number 72-54-8; EU number 200-783-0). h If Member States do not apply EQSs for biota, they shall introduce stricter EQSs for water in order to achieve the same level of protection as the EQSs for biota set out in Article 3(2). They shall notify the Commission and other Member States, through the Committee referred to in Article 21 of Directive 2000/60/EC, of the reasons and basis for using this approach, the alternative EQSs for water established, including the data and the methodology by which they were derived and the categories of surface water to which they would apply. i For the group of priority substances of PAHs (No. 28), each individual EQS is applicable, that is, the EQS for benzo(a) pyrene, the EQS for the sum of benzo(b)fluoranthene and benzo(k)fluoranthene, and the EQS for the sum of benzo(g,h,i) perylene and indeno(1,2,3-cd)pyrene must be met.

High

Analytical Techniques for the Determination of Organic and Organometallic Analytes

309

Ion pairing-LC and ion chromatography w. ESI-MS or ICP-MS

LC-ESI-MS

Polarity

LC-APCI-MS

FFF with ESI-MS or ICP-MS

LC-APPI-MS

Low

GC/MS

Low

SEC with ESI- or APCI-MS

Molecular weight

High

FIGURE 13.4 Important separation techniques for organic and organometallic contaminants, classified according to the criteria of molecular size and polarity and the possibility to be coupled with mass spectrometric detection.

constituents. Depending on the chemical nature and particularly the volatility of the analytes, either gas chromatography (GC) or liquid chromatography (LC) is used. In rare cases, ion chromatography (IC) is also used to separate organic analytes when these are ionic or ionizable compounds. However, the last technique has the drawback that its typical mobile phases are not very compatible with (molecular) mass spectrometric detection, which is nowadays the most sensitive and versatile technique. Capillary electrophoresis (CE) also covers a similar range of application as IC, but is used even less frequently in environmental analysis, for the following reason: it is capable of handling only very small sample volumes, so the concentration detection limits of this method are rather poor and often inadequate for the determination of organic and organometallic compounds at trace and ultratrace levels. Figure 13.4 gives an overview of the range of applicability of the various separation techniques in terms of molecular weight and polarity and their combination with mass spectrometric detection. In the following, important instrumental implications of the common separation and detection techniques will be discussed.

13.2.2 SEPARATION TECHNIQUES 13.2.2.1 Gas Chromatography GC continues to play a key role in the separation of sufficiently volatile organic and organometallic compounds in environmental samples.15 Current instruments provide various inlet options that can be selected according to the particular sample and matrix.16 In order to reach maximum sensitivity, either splitless injection (in a split/splitless injection port) or on-column injection is used. The latter technique is particularly suitable for thermally labile compounds, for example, toxaphenes or organophosphorus pesticides, since the sample is injected directly to the head of the analytical column or a precolumn, where it is gently vaporized as the injector and column temperatures rise. Cold-on-column (COC) injection also minimizes sample discrimination, which occurs with split/ splitless injectors when analyte mixtures spanning a broad range of boiling points, for example, polycyclic aromatic hydrocarbons (PAHs), are injected. Programmable temperature vaporizer (PTV) injectors are a third common injector option, particularly versatile in reducing the degradation of thermally labile compounds and for minimizing split discrimination.17 They can be used for

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Analytical Measurements in Aquatic Environments

small volumes £5 μL (where their function resembles that of a COC injector) or with large injection volumes (10–400 μL). The latter is particularly useful for environmental trace analysis, since it allows sensitivity to be increased proportionally to the injection volume. For large injection volume, the PTV liner is filled with an adsorbent (e.g., Tenax) that retains the analytes at a low temperature during the injection step while the large solvent volume is vented. The increase in PTV temperature desorbs the trapped analytes and transfers them to the GC column. This setup is not only attractive for large volume injection, but also allows the on-line coupling of LC and GC18 or the coupling of on-line solid-phase extraction (SPE) with GC.19 Figure 13.5 illustrates typical instrumental implementations of this setup. Apart from offering the possibility of large volume injection, the PTV injector has several practical advantages over the on-column injector, the two most important being that it does not require a large inner diameter precolumn (since the injection needle does not have to enter the column as in on-column injection) and that it is much more tolerant of dirty samples. Any nonvolatile sample constituents will remain in the packed liner instead of going to the head of the GC column, and the liner is easily replaceable. There is even the possibility of having the liner exchanged automatically after every injection if particularly dirty samples are run; probably, however, this approach is more useful in food and cosmetic product analysis than in environmental analysis.20 To meet the high demands of organic trace analysis,21 GC columns have been subject to continuous refinement. This refers not only to the reduction in diameter of the nowadays almost exclusively used capillary columns (separation efficiency increases with decreasing capillary diameter), but also reflects the development in stationary phase technology: In order to reduce column bleed (which is essential for mass spectrometric detection), highly cross-linked stationary phases are used to (a)

Syringe

LC pump

DAD 1 mL

2 mL loop

Samples Waste GC injector (b) 2 + GPC Syringe

LC pump

DAD 4–7 mL

20 mL loop

Samples Waste GC injector

FIGURE 13.5 Schematic setup of system configurations for: (a) on-line SPE-GC and (b) on-line LC-GC with a large volume injection into GC. (Reprinted from Kerkdijk et al. 2007. Anal. Chem. 79: 7975–7983. With permission.)

Analytical Techniques for the Determination of Organic and Organometallic Analytes

311

provide clear blanks even at higher temperatures (columns of this type are often denoted by the suffix “MS,” e.g., DB5MS). GC columns for polar analytes of the wax type [based on cross-linked polyethylene glycol (PEG) stationary phases] have always been limited to relatively low working temperatures to minimize thermal decomposition. Here, the introduction of stationary phases based on the sol-gel process with embedded PEG groups has substantially extended the application range, making their use at temperatures up to 350°C possible.22 One of the most recent additions to the range of GC stationary phases are GC columns using ionic liquids as stationary phases.23 Although the separation power in terms of the theoretical plate height of these columns is still inferior to siloxane-based columns, they offer a very interesting and unusual range of selectivity that may help to resolve mixtures that are inseparable on classical types of GC columns. Moreover, the very different separation behavior of GC columns with stationary ionic liquid phases as compared to that of typical apolar or even polar GC columns makes the former very interesting candidates for twodimensional GC (GC ¥ GC), providing a less correlated retention behavior in the two dimensions than with other types of GC stationary phases.24 In recent years, GC ¥ GC has also increased significantly in importance and in the number of applications. The coupling of two dimensions of gas chromatographic separations with sufficiently different, and in the ideal case, orthogonal retention characteristics admits the possibility of resolving mixtures of a complexity, which cannot be resolved in one single chromatographic dimension. The key to this technique is the use of a suitable modulator that collects fractions of the eluate from the first separation dimension and transfers these quantitatively to the second dimension, where the mixture is resolved in a rapid separation (typically taking from one to a few seconds) on a relatively short column (1–2 m). The data of the many short chromatograms are combined to produce the typical “contour plots” (Figure 13.6).25 Although GC ¥ GC has been used extensively with “structured” samples, for example, mixtures of hydrocarbons of various homologous series in the petrochemical industry, it has rather rarely been used to resolve the complexity of unstructured environmental samples.27 The enormous advantage of this technique for the analysis of complex environmental samples is that it can produce practically uninterfered chromatographic peaks, which enable straightforward identification by mass spectrometry (MS). However, only very fast MS detectors are capable of being used in GC ¥ GC—typically only time-of-flight-MS (TOF-MS) instruments, fast scanning quadrupole MS instruments, or unspecific detectors such as flame ionization detector (FID), electron-capture detection (ECD), or flame photometric detection (FPD) if no structural information is required. Given a typical peak width in the second dimension chromatogram of 30–50 ms, plus the need to obtain about three data points along the peak for qualitative analysis and at least 10 data points for quantitative analysis, explains why data acquisition rates of 50–200 Hz are required. 13.2.2.2 Liquid Chromatography It appears that over the last decade high-performance liquid chromatography (HPLC) with its different modes of operation is overtaking GC in its importance and the number of applications in environmental analysis. The reasons for this are various: first, many of the anthropogenic contaminants of the hydrosphere are not amenable to GC because of their polarity or molecular weight. Second, it must be borne in mind that the water column is not only a reservoir, but a reactor in which degradation and metabolization of organic compounds takes place. This means that even if the parent compounds initially released into the water body are apolar, their metabolites usually are not because metabolization or degradation render the compounds more hydrophilic. Third, it should be mentioned that for many years LC had a significant disadvantage in comparison to GC in that coupling with MS was difficult to implement. With the introduction of modern atmospheric pressure ionization (API) interfaces,28,29 however, this is no longer the case, and simple (quadrupole) mass spectrometers at least can be used as detectors for LC in the same straightforward way as in gas chromatography-mass spectrometry (GC-MS). Although LC separation does not normally provide the same high resolving power as GC with long capillary columns, it can be better tuned to achieve the necessary resolution. In addition to the

312

Analytical Measurements in Aquatic Environments 10 9 8 7 6 5 4 3 2 1 0

10 (b) 9 8 7 6 5 4 3 2 1 0 20 80 10

(a)

10

20

30

40

50

60

70

30

40

50

60

70

80

8 (c) 7 Toxaphene

2nd dimension retention time (sec)

6 5 4

PCTs 3 PCAs

2 1 0 10 10

20

30

40

50

60

70

80

90

(d)

9 8 7 6 5 4 3 2 PCAs

1 0 10

20

30

40

50

60

70

80

1st dimension retention time (min)

FIGURE 13.6 GC × GC–mECD overlay plot of various pollutant groups on a DB-1 × 007-65HT column combination. Pollutant groups: (a) (䊏) PCDTs and (䊏) PCDD/Fs; (b) (•) PCDEs and (•) PBDEs; (c) (•) PCBs, (•) PBBs, (•) PCDEs, (•) PBDEs, (•) PCDTs, (䊐) PCNs, (䊏) PCDD/Fs, (X) OCPs, (X) individual toxaphene standards, and PCAs (PCA-60); (d) PCAs (PCA-60), PCTs (Aroclors 5442 + 5460), and toxaphene technical mixture. (Reprinted from Korytar et al. 2005. J. Chromatogr. A 1086: 29–44. With permission.)

Analytical Techniques for the Determination of Organic and Organometallic Analytes

313

choice of stationary phase, mobile phase conditions can be varied widely in terms of composition, pH, temperature, and so on, thus allowing the separation to be optimized as required. Whereas the “classical” 25 cm × 4 mm ID columns with 5 μm particles used to be a widely used format, many laboratories have now moved to smaller formats, for example, 10 or 15 cm columns with 3 μm particles, and have also reduced the column diameter. In accordance with chromatographic scaling laws, the resolution should essentially remain unaltered if column length and particle diameter are reduced by the same factor. While the positive effect of reduced column length on the system pressure is normally more than offset by the reduced particle diameter, the reduction in separation time is evident. The decrease in column diameter (to 3 or 2 mm) brings about a significant reduction in solvent consumption (proportional to the square of the column diameter), which may be an important economic argument. Moreover, the slower flows through narrow-bore columns are often better compatible with the requirements of MS detection. Most recently, columns packed with particles of 1.7 or 1.8 μm diameter and 30–50 mm in length have come onto the market. These columns provide superior separation properties, but they create a backpressure that can be handled only with new generation HPLC systems, operating under trade acronyms such as UPLC (“ultrahigh pressure/ ultraperformance liquid chromatography”) or RRLC (“rapid resolution liquid chromatography”). Stationary phase technology has also seen significant improvements over the past years. The silica base material is nowadays often a hybrid material, synthesized from tetraalkoxysilanes and functionalized trialkoxysilanes, for example, methyl-trimethoxysilane (MTMS). The introduction of alkyl-trialkoxysilanes into the silica backbone makes the material more resistant to hydrolytic attack and also improves their separation behavior for basic analytes.30 C18 (= octadecylsilane) stationary phases are still the materials typically used in environmental analysis, and the enormous choice of materials with gradually different properties allows columns to be selected that are particularly well suited to a given separation task.31 Reversed phase separations with materials of shorter alkylsilane chain length (C8, C4, and C1) are less frequently used. Normal phase (NP) separations are comparatively rarely used in environmental analysis. Again, the reasons lie in the range of analytes amenable to this mode of separation, and in the limited compatibility of typical normal phase HPLC (NP-HPLC) mobile phases with mass spectrometric detection (this also applies to IC). Not only for this reason has interest recently grown in hydrophilic– lipophilic interaction chromatography (HILIC), which represents a viable alternative to the separation of very polar compounds with mobile phases that have a much better compatibility with MS detection, for example, acetonitrile/water with a low water content, typically below 10%.32 Nonetheless, NP chromato-graphy retains its important role in sample preparation, particularly for the cleanup of complex environmental samples. In the off-line approach, fractions are collected and the relevant one is injected into the reversed phase HPLC (RP-HPLC) system, often after solvent exchange. In parallel with recent developments in GC, multidimensional HPLC (LC × LC) is now also finding application in environmental analysis.33 The combination of two sufficiently different separation dimensions (e.g., NP-HPLC × RP-HPLC or IC × RP-HPLC), however, remains difficult because of the solvent compatibility issues discussed above. Here, too, HILIC may bring about a significant improvement, since its mobile phase requirements are much closer to RP-HPLC than those of other liquid chromatographic techniques.34 In contrast to GC × GC, LC × LC cannot be implemented with a (thermal) modulator that collects the analytes after the first separation dimension and reinjects them into the second column; it is most practically realized with a double-loop interface that alternately collects and transfers the analytes from the first to the second dimension (Figure 13.7). Even though the second dimension chromatogram is also very fast, detection is not normally a problem since the peak widths in the second dimension are usually still of the order of 1–2 s. 13.2.2.3 Capillary Electrophoresis Compared to GC or HPLC, CE is used far less frequently for the environmental analysis of organic compounds.35,36 In the case of organometallic speciation, there appears to be a gradual increase in the

314

Analytical Measurements in Aquatic Environments

(a)

Gas chromatograph

Sampling inlet

Carrier gas flow Detector

Capillary column

2nd dimension column

Secondary oven

Main oven

1st dimension column

Thermal modulator

(b)

Loop 1

Column 1

Column 2

Pump 1

To detector

Pump 2

Loop 2

FIGURE 13.7 Instrumental setup of (a) a GC ¥ GC system (Anon., GC ¥ GC Comprehensive TwoDimensional Gas Chromotography Form No. 209-184 R2.58-REV-1; LECO Corporation, St Joseph, MI 49085; P3, 2008. With permission.); (b) a LC × LC system based on a second-dimension column with two storage loops (T. Hyotylainen, LC x LC switching valves configuration; Chromedia Amsterdam; P “Two Dimensional LC (LC ¥ LC),” 2008. With permission.).

use of this technique in comparison to the chromatographic methods.37,38 This is easily explained, first, by the need for an analyte to be charged (at least under the conditions of separation) for it to be separable by CE, and, second, by the relatively low concentration sensitivity of CE. This calls for suitable preconcentration techniques which, as with isoelectric focusing, can even be performed on-line.39 Only with (electrospray) mass spectrometric detection or with fluorescence detection is CE sufficiently sensitive to detect analytes at environmentally relevant (ppb- and sub-ppb-)concentration levels. Here, speciation analysis has an enormous advantage over organic analysis: it can be coupled

Analytical Techniques for the Determination of Organic and Organometallic Analytes

315

to ultrasensitive element-specific detection by inductively coupled plasma-mass spectrometry (ICP-MS), rather than molecule-specific detection by electrospray ionization-mass spectrometry (ESI-MS). Moreover, because many environmentally relevant organometallic compounds are ionic, they would have to be derivatized to make them amenable to GC separation.40 13.2.2.4 Other Separation Techniques Few other separation techniques have been used to a larger extent for the analysis of organic and organometallic compounds in water samples. Among these, micellar electrokinetic chromatography (MEKC)—a hybrid between electrophoresis and chromatography with a pseudostationary phase created by micelles dissolved in the electrophoresis buffer—is quite widely applied in water analysis.41,42 Ion chromatography is less often employed for the analysis of organic pollutants, mostly because the mobile phase is not easily compatible with atmospheric pressure ionizationmass spectrometry (API-MS) detection unless a suppressor module is used to remove the additives of the mobile phase after it has passed through the ion exchange column.43,44 In contrast, IC is a most versatile tool for speciation analysis, particularly in combination with ICP-MS detection. There are thus numerous reports on the speciation analysis of arsenic,45,46 selenium,47,48 chromium,49,50 and antimony,51 as well as on simultaneous multielemental speciation analytics.52,53 13.2.2.5 Size Exclusion Chromatography This is a common separation technique in the analysis of natural and synthetic polymers. Since it separates compounds according to their molecular size (which is approximately proportional to the cubic root of their molecular weight) and its separation efficiency is relatively poor in terms of the number of peaks that can be resolved in one run, it tends to be used as a sample preparation and cleanup technique rather than for analytical chromatography. The few examples published on the use of size exclusion chromatography (SEC) as a single separation technique for the characterization of organic substances thus refer to the analysis of dissolved organic matter/humic substances in water,54,55 rather than to the actual characterization of organic analytes in water samples.56 In contrast to this, there are more reports on the use of SEC for speciation analysis, since this technique allows metals to be distinguished that are associated with the high- or low-molecular-weight fraction of a water sample. In the former case, this means that the metal is bound to larger humic or fulvic acid associates, whereas in the latter case, the metal is either present in free form or complexed by small inorganic or organic ligands.57,58 Related to SEC separation in its separation ability is field flow fractionation (FFF). Being a nonchromatographic separation technique, FFF is also used to separate molecules and even colloids according to size in a long, very thin separation channel (typically, 20–50 cm in length and 100–250 μm in thickness) in which a laminar flow profile is established. Like SEC, FFF is also a low-resolution separation technique, which only allows the fractionation of samples or yields information about which fraction metals or certain metal species are bound to.59,60

13.2.3

DETECTION TECHNIQUES

The large majority of chromatographic separations in environmental analysis are nowadays performed by mass spectrometric detection. The reasons for this are the following: • Its sensitivity. • The structural information available from MS. • Its general applicability. All alternative detection schemes fail in at least one of the above criteria, and mass spectrometric detection has replaced other detectors even in applications in which they were well established, such as ECD for the gas chromatographic determination of organochlorine pesticides,61 or atomic emission detection (AED) or FPD in the GC analysis of organotin (OT) compounds.62

316

Analytical Measurements in Aquatic Environments

Recent years have witnessed rapid advances in MS instrumentation; the most important features of the particular types of mass spectrometers will now be discussed briefly. 13.2.3.1 Quadrupole Mass Spectrometers They are still the workhorses of coupled mass spectrometric applications, as they are relatively simple to run and service, relatively inexpensive (for a mass spectrometer), and provide unit mass resolution and scanning speeds up to approximately 10,000 amu/s. This even allows for simultaneous scan/ selected ion monitoring (SIM) operation, in which one part of the data acquisition time is used to scan an entire spectrum, whereas the other part is used to record the intensities of selected ions, thus providing both qualitative information and sensitive quantitation. They are thus suitable for many GC-MS and liquid chromatography-mass spectrometry (LC-MS) applications. In contrast to GC-MS with electron impact (EI) ionization, however, LC-MS provides only limited structural information as a consequence of the soft ionization techniques commonly used with LC-MS instruments [electrospray ionization (ESI) and atmospheric pressure chemical ionization (APCI)]. Because of this limitation, other types of mass spectrometers are increasingly gaining in importance for LC-MS. 13.2.3.2 Ion Trap Mass Spectrometers These are compact ion storage devices that can be operated in such a way that they sequentially eject ions of a defined mass-to-charge ratio onto the detector. Control of the electrical field and voltages applied to the ion trap allows the entire spectrum to be scanned, typically at low (unit) resolution and scanning speeds comparable to those of a quadrupole mass analyzer. Ion traps can provide full-scan spectra for lower amounts of substance than quadrupole mass spectrometers, as they store a larger fraction of the ions formed. A further advantage of this type of mass spectrometer is that it can be used for higher-order MS (MSn) experiments. In these, the so-called precursor ion is isolated in the trap and subjected to further fragmentation by the application of an RF pulse. The fragments thus formed are further analyzed. Since this sequence can be repeated several times, it is possible to obtain mass spectra of higher orders (typically, up to MS5 . . . MS6) before the signal intensity becomes limiting. 13.2.3.3 Triple Quadrupole Mass Spectrometers Triple quadrupole or MS/MS instruments have seen increased use in recent years for applications where qualitative and quantitative analyses are equally important. They consist of three quadrupoles coupled in series, the first and third of which (Q1 and Q3) can be scanned by variation of the DC and RF voltages applied. The second quadrupole (Q2) essentially functions as a collision chamber in which ions that have been passing through Q1 are fragmented by collision with the collision gas (argon) at reduced pressure. The fragments are then analyzed in Q3. The most common mode of operation for triple quadrupole instruments is the multiple reaction-monitoring (MRM) mode. In general, MRM is performed by scanning Q1 and Q3 while using Q2 as the collision cell. This mode of operation offers superior selectivity compared to single-quadrupole MS detection, since one characteristic precursor ion can be selected and thus isolated from the background. It is thus used particularly in multiresidue methods, even if chromatographic resolution cannot be achieved for all the relevant analytes.63 Furthermore, fragmentation can be induced and characteristic mass spectra produced even with soft API techniques. This can in part also be realized by single-quadrupole instruments with in-source collision-induced dissociation (CID), but again with poor selectivity and also reduced sensitivity.64,65 Further modes of operation of triple quadrupole instruments are the neutral loss scan, where Q1 and Q3 scan with a constant offset. This mode can be used for groupspecific detection in complex samples. It has, for example, been successfully used for the HPLCESI-MS/MS detection of aromatic carboxylic acids by monitoring the neutral loss of m/z 44 (corresponding to the loss of CO2).66 Finally, a precursor scan (with Q1) can be performed to detect, with Q3 held at a fixed m/z value, all precursors that produce a specific fragment. Provided the fragment ion is specific to a certain functional group, this type of analysis also provides screening for compounds containing a given functional group. An example of this mode of operation is the

Analytical Techniques for the Determination of Organic and Organometallic Analytes

317

detection of aldehydes, dicarbonyl-, and hydroxycarbonyl compounds based on the monitoring of specific fragments of their 2,4-dinitrophenylhydrazine (DNPH) derivatives.67 In the case of aldehydes, a fragment ion at m/z 163 is characteristic, whereas for dicarbonyl- or hydroxycarbonyl compounds, the DNPH derivatives produce fragment signals at m/z 182. 13.2.3.4 Time-of-Flight (TOF) Instruments TOF-MSs have nowadays largely replaced the double-focusing sector field instruments earlier used for high-resolution measurements. Different from all other types of mass analyzers, TOF instruments utilize a field-free zone, the flight tube, in which, because of their different masses, ion packages travel with different velocities after they have taken up the same kinetic energy. The exact m/z ratio of the ion is calculated from the time needed to arrive at the detector. To achieve high mass resolution (typically, R = m/Dm ≥ 10,000), reflectron-based TOF instruments are used. In these, the ion does not have a linear flight path, but is reflected at one end of the flight tube by a “magnetic mirror” and travels back to the detector. This minimizes the energy dispersion of the ions, which is necessary to achieve high resolution. TOF instruments always provide scan data at repetition rates of up to 20 kHz (although typically tens to hundreds of spectra are co-added on board the MS to reduce the amount of data and improve the signal-to-noise ratio, leading to 50–200 spectra per second). For the identification of unknowns, hybrid quadrupole-orthogonal acceleration time-of-flight mass spectrometers (Q-oa-TOF-MS or Q-TOF-MS) are used.68-70 The determination of the exact fragment or precursor ion mass allows elemental formulas to be calculated and structures to be assigned for the unknowns, as shown for various metabolites.70 Despite their evident advantages, the use of TOF and hybrid TOF instruments is still limited owing to their significantly higher investment costs than for quadrupole or ion trap instruments. 13.2.3.5 Fourier-Transform Ion Cyclotron Resonance Instruments If ultrahigh resolution (R up to 100,000) is required, Fourier transform ion cyclotron resonance mass spectrometers (FT-ICR-MS) may provide the solution. These operate on the principle of detecting the minute currents induced in a detector by ion packages of a defined mass-to-charge ratio circulating in an orbit in a very strong magnetic field. The exact frequency of circulation depends on the m/z ratio and can be calculated from the Fourier-(back-)transformation of the detected signal. The extremely high mass resolution can be used to obtain exact mass data even for high-molecularweight compounds. Although this technique has not yet been used for environmental contaminants in the hydrosphere, it has already been used to characterize dissolved organic matter (humic and fulvic acids) in aqueous samples.71-73 13.2.3.6 Ionization Techniques For GC-MS, most applications use EI ionization. This produces information-rich spectra with an abundance of fragment ions and mostly readily detectable molecular ions that can be searched for in commercial or purpose-built libraries.74 Chemical ionization (CI) is of limited use for screening analysis, since in the virtual absence of fragmentation it provides only molecular weight information, but hardly any structural information. For LC-MS, API techniques have almost completely replaced the earlier successful techniques of LC-MS interfacing and ionization due to their significantly greater ease of use and robustness. Their only drawback is that they are soft-ionization techniques that typically produce molecular ions (M+ or M-) or quasi-molecular ions ([M + H]+ or [M - H]-), and very few fragment ions, if any at all, under normal conditions. This disadvantage can be overcome by the above-discussed in-source CID, or by the use of hybrid instruments—the former at the cost of sensitivity, the latter for a significantly higher financial investment. Moreover, the two main API techniques, ESI and APCI have the disadvantage that they are essentially applicable only to polar–ionic analytes.75 For less polar analytes, an atmospheric pressure photo-ionization (APPI) source has been developed,76 which has successfully been used for the analysis of, for example, PAHs77 or endocrine disruptors.78 Modern LC/MS instruments also feature dual ionization sources, such as combined ESI/APCI79 or APCI/APPI80 sources.

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Analytical Measurements in Aquatic Environments

13.2.3.7 Inductively Coupled Plasma-Mass Spectrometry Inductively coupled plasma represents a further important ionization source for mass spectrometry (ICP-MS), but which, however, provides elemental rather than molecular information due to the fact that the sample is introduced in a highly energetic, high-temperature plasma (with temperatures reported to approach 10,000 K).81 In this plasma, analytes are almost completely atomized and ionized, which enables their subsequent mass spectrometric detection with several of the abovementioned mass analyzers, notably quadrupole- and TOF-MS. In many practical applications, however, it is found that this is not always the case and that molecular fragments survive in the plasma and contribute to the spectral background. For this reason, ICP-MS instruments have been developed, which have a collision or reaction cell between the ion source and the mass analyzer. Similar to a triple-quadrupole instrument, this cell can be used to collide the ions formed in the plasma with an inert gas (e.g., argon in the case of a collision cell) or a reactive gas (e.g., oxygen in the case of a reaction cell) to remove molecular interferences by either breaking up the molecular fragments or creating stable oxide ions that have a mass-to-charge ratio that is not interfered.82 Most frequently, ICP-MS is used with quadrupole mass analyzers, although TOF instruments are also becoming popular for this range of applications. The molecular structural information for organometallic species has to be derived from chromatographic separation or the parallel use of molecular (ESI) and atomic mass spectrometry (ICP-MS). This, however, is not always an easy task owing to the significant difference in sensitivity of the two detection techniques (ICP-MS is typically two to three orders of magnitude more sensitive than ESI-MS in the full-scan mode), and the different tolerance of the ionization techniques to buffer concentrations and mobile phase compositions.83,84

13.2.4

SAMPLE PREPARATION FOR CHROMATOGRAPHIC ANALYSIS

Despite the remarkable sensitivity of modern instrumental detection techniques, analysis of environmental water samples nearly always requires enrichment of the analytes. This, together with separation from the matrix, are the two main functions of sample preparation; appropriate sample preparation techniques address both issues at the same time, while striving to impose as few restrictions as possible on the subsequent instrumental determination (separation and detection). Sample preparation is strongly dependent on the nature of the analyte and the matrix, particularly with regard to its volatility and polarity. Figure 13.8 gives a general overview of common sample preparation (enrichment) techniques for aqueous and other matrices. Volatile compounds (solvents, alkyl-element species, etc.) can be isolated and enriched from the headspace (HS) of an aqueous sample.85 HS techniques can be divided into static and dynamic HS techniques. In the former, a fraction of the HS over an aqueous sample is withdrawn after its thermal equilibration and introduced into the gas chromatograph for analysis. The technique is very easy to perform and automate, but does not provide high sensitivity, since it relies on the equilibrium between the liquid and gas phases, which usually means that only a small fraction of the analyte can be transferred to the GC system.86-88 It has nevertheless found widespread application in environmental analysis, for example, for the determination of halogenated and aromatic solvents in water samples.89 To overcome the lack of sensitivity and the strong influence of the matrix in static HS analysis, which requires the use of appropriate internal or surrogate standards for quantitation,90 dynamic HS is often preferred for sample preparation. In this technique, also called purge and trap (P&T) sample preconcentration, the analytes are exhaustively extracted by passing an inert gas stream (typically the carrier gas He) through or over the sample to liberate the purgeable compounds and to transport them to an adsorbent trap. On completion of the purge step, the analytes are thermally desorbed from this trap and injected into the GC.91 The trap material has thus to be chosen with particular consideration of the analytes in order to ensure their efficient trapping during the purge step, and their complete recovery in the desorption step. Multiadsorbent traps are available to tailor the trapping properties as desired. Since extraction is normally performed to completion, P&T techniques are significantly more sensitive than static HS techniques. Even so, special measures

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Sample matrix None

Direct aqueous injection (DAI)

Static headspace with gas syringe (SHS)

Extractant phase

Cryogenic zone

Dynamic headspace/ purge & trap (P&T) • Purge-and-cryogenic trapping

Solvent

• Liquid/liquid extraction (LLE) • Headspace-solvent− • Steam distillation/extraction microextraction (HS-SME) (SDE) - Headspace single-drop • Solvent microextraction (SME): microextraction (HS-SDME) - Headspace liquid phase – SDME microextraction (HS-LPME) – LPME – DLLME

Sorbent/ solid phase

• Solid phase extraction (SPE) • Solid phase microextraction (SPME) • Stir bar sorptive extraction (SBSE) • INCAT/OTT/in-tube-SPME • SPDE

Membrane

• SLM • MMLLE • PME • MASE

• MESI • MIMS • HF-LPME • LGLME

• Headspace-solid phase microextraction (HS-SPME) • Headspace stir-bar sorptive extraction (HS-SBSE)

• Purge-and-sorbent trapping • Spray-and-sorbent trapping

• Headspace-solid phase dynamic extraction (HS-SPDE)

• Purge-and-membrane extraction • Headspace/membrane extraction w. sorbent interface (HS-MESI) • Headspace/membrane inlet mass spectrometry (HS-MIMS)

FIGURE 13.8 Graphical overview of sample preparation techniques for organic and organometallic analytes in aqueous samples. For explanation of the abbreviations, see Table 13.2. (After Demeestere et al. 2007. J. Chromatogr. A 1153: 130–144.)

have to be taken to handle the significant amounts of water vapor removed from the sample and trapped on the adsorbent. They include • The use of hydrophobic adsorbents combined with a dry-purge step in which loosely bound water is removed from the adsorbent trap92 • The use of membrane driers to remove water vapor during the sampling step before arriving at the adsorbent trap93 • Cryogenic removal (freezing-out) of the water vapor94 LODs obtained with P&T techniques are typically in the ng/L to low μg/L range and thus often 100 to more than 1000 times lower than those achieved with static HS techniques. P&T does have shortcomings, however. The main ones are95 • The more complex instrumentation required than in static-HS-GC analysis, particularly if on-line and real-time monitoring is to be performed • The necessity for a very efficient water management system • The possibility of cross-contamination • Foaming The time required per analysis—in the 10–30 min range—is approximately the same as for static HS-GC but does not allow parallel sample preparation of multiple samples, since the trapped analytes have to be injected directly into the GC.96

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In an attempt to overcome the significant difficulties that the presence of water vapor poses to the analysis of very volatile compounds, purge-and-membrane extraction techniques have been developed that largely prevent the introduction of water into the analytical system. Typical implementations of this form of sample introduction have been called by its developers “membrane extraction with a sorbent interface” (MESI),97 or membrane introduction mass spectrometry (MIMS).98,99 They are based on a silicone hollow-fiber membrane that is inserted into the sample to be monitored, and the passing of a certain volume of inert gas through the membrane. Volatile compounds permeate the membrane and are swept to the adsorbent trap from which they are desorbed into the GC. This method of sample introduction is particularly suited for field and process monitoring and for dirty samples, since it prevents any nonvolatile compounds from entering the analytical system.100 A revolutionary development in the field of sample preparation for volatile and semivolatile organic and organometallic compounds was the introduction of solid-phase microextraction (SPME) by Belardi and Pawliszyn101 in 1989. This tool, which in the initial phase was a fused silica fiber with a polymer coating in a modified syringe-like holder, allowed organic analytes to be extracted from aqueous samples by either HS extraction (HS-SPME) or direct immersion (DI-SPME). After a defined time, or after partitioning, equilibrium between the sample and the fiber coating has been reached, the fiber is withdrawn from the sample and introduced into the injection port of the GC where it is thermally desorbed (Figure 13.9). This procedure offers a number of advantages over conventional (static) HS and liquid extraction techniques for sample preparation. The major ones are the following: • The elimination of organic solvent use • The ability to tune the selectivity of enrichment by appropriate choice of the polymer coating of the fiber • The relatively high degree of enrichment with appropriate choice of polymer material and dimensions (film thickness) despite being an equilibrium technique • The introduction of relatively low amounts of water when using hydrophobic fiber materials • The ability to extract from small to large sample volumes (from less than 1 mL to 1 L or even more)

(a)

(b)

Xylene

Response (pA*s)

Toluene

Benzene

Extraction time (min)

FIGURE 13.9 Principle of SPME. (a) Extraction in a closed vessel by DI or the use of an SPME device. (b) Desorption of analytes from the fiber in the GC injection port. The graph in the middle corresponds to the amount of substance introduced in the GC. The signal due to the analytes increases with increasing hydrophobicity and extraction time.

Analytical Techniques for the Determination of Organic and Organometallic Analytes

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• The ability to sample from solid, liquid, or gaseous samples • The possibility of automation • No complicated or expensive instrumentation is needed (although the extraction fibers have to be regarded as relatively expensive consumables) Because of these distinct advantages over classical extractive sample preparation techniques, it is easy to understand why SPME has become one of the most popular sample preparation techniques for water analysis. Numerous monographs and reviews document this great popularity and discuss in detail the theory and practice of SPME,102,103 as well as applications in the field of environmental analysis104,105 and speciation analytics.106,107 The general versatility of this technique is limited only by its unsuitability for efficiently extracting analytes with a low affinity for the polymer coating (corresponding to low KOW partitioning coefficients), which reduces the sensitivity of this method. One way of overcoming this drawback is to increase the volume ratio of the extracting phase/water sample, which has been done in the form of a stir-bar coated with polydimethyl-siloxane (PDMS). This is essentially the same material as the apolar coating of SPME fibers but is used with a substantially larger volume (50–200 μL instead of approximately 0.5 μL of the SPME fiber coating). The extraction efficiency thus assumes ≥90% already for KOW values of 103 (compared to £5% for SPME).108 After reaching equilibrium (or after a predetermined time), the analytes are desorbed from the PDMS-coated stir bar (providing the technique with the acronym SBSE, “stir-bar sorptive extraction”) either with a suitable solvent or by thermal desorption. A commercial unit is available for the thermal desorption of the PDMS-coated stir bars. In the case of solvent desorption, GC or LC analyses are possible. In comparison to thermal desorption, solvent desorption for SBSE has a significantly lower sensitivity, since the enriched analytes are desorbed in a large solvent volume of which only a small fraction can normally be introduced into the GC or LC. Several variations of the basic idea—a sorptive enrichment and sample introduction device—have been reported over the last decade that offer alternatives or sometimes improvements over the classical SPME technique. An overview of these techniques with their principle of operation is given in Table 13.2 and in two reviews.108,109 Although the miniaturization of extraction and enrichment steps is attractive for a variety of reasons, much work, particularly in routine laboratories, still relies on “classical”, that is, conventional scale extraction techniques, which have the reputation of being more robust, particularly for the extraction of samples with difficult matrices. These are solvent extraction (liquid–liquid extraction, LLE) and SPE. Although LLE is probably the most versatile and flexible extraction technique in that it specifically allows the extraction medium to be selected according to the analytes of interest, it will most likely be phased out from the analytical laboratory to reduce the consumption of volatile and/or toxic solvents. There is a growing interest in the so-called green solvents (which are much less toxic, readily biodegradable, and have a negligible vapor pressure), but this topic needs to be developed still much further.110 In contrast to this, SPE in its different formats continues to be used widely for environmental analysis.111-113 This allows the enrichment of large water volumes in off-line, at-line, and on-line modes, all of which can be automated by suitable instrumentation. Off-line SPE offers the greatest flexibility: different solvents can be used for conditioning, washing, and eluting the cartridges; the elution volume is not critical as it can be reduced; and the solvent can even be exchanged for subsequent analysis. At-line analysis (which in this context denotes the automated enrichment of samples on SPE cartridges, and their subsequent elution and injection into the chromatographic system, whereby only an aliquot of the eluate is injected) is similar in this respect, with only the minor reservation that the sample preparation step should not take much longer than the chromatographic run; otherwise, it will limit sample processing frequency. Both off-line and at-line SPE can be performed with the same format of SPE cartridges or SPE-disks, the latter being particularly advantageous with their larger surface area when large sample volumes containing suspended matter are to be enriched.114

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TABLE 13.2 Overview of Extraction/Sample Preparation Techniques Derived from or Related to SPME Acronym

Name of the Method

CME

Capillary microextraction

ESD

Equilibrium sampling device

HSPE

Headspace solvent microextraction

INCAT

Inside-needle capillary adsorption trap

In-tube SPME In-tube solid-phase (ITSPME) microextraction ITE In-tube extraction

LPME

Liquid-phase microextraction

MEPS

Microextraction in a packed syringe

Micro-LLE

Micro-liquid– liquid extraction Needle trap

NT

OTME OTT

Open-tubular microextraction Open tubular trap

Principle/Characteristics Fused silica capillary of up to 40 cm coated internally with the stationary phase; analyte elution by solvent Use of PDMS membrane that equilibrates with the surrounding water sample HS extraction of volatile compounds into a single drop of solvent, which is then injected into the GC Combination of SPME and P&T methods: a hollow needle with either a short length of GC capillary column placed inside it, or an internal coating of carbon, is used as the preconcentration device. Sampling by passing the gas or liquid through the device either actively with a syringe or passively via diffusion Internal polymer-coated fused silica (GC) column through which the sample is drawn for enrichment while analytes are eluted on-line into the HPLC

LLE with a minute amount of solvent, typically one microdrop, exposed at the tip of a microliter syringe, which is then withdrawn after extraction and injected into the GC Sample enrichment on a small amount (1–2 mg) of solid material inserted into a syringe (100–250 mL) as a plug. Elution with a suitable solvent As LPME Device with a hypodermic needle, whose tip is filled with a solid adsorbent onto which the sample is adsorbed. For desorption, which takes place inside the GC injection port, the carrier gas flow is forced through the needle, entering it through a hole at its side

Application(s) Suited for on-line SPE-HPLC, for example, with MTMS/ PEO-coated capillary Extraction of halogenated compounds from sea and river water samples For volatile, GC-amenable compounds, particularly in water and flavor analysis Sampling of gaseous samples, solutions, or the solution HS

Relatively small sample volumes (£1 mL) of medium- to nonpolar analytes are enriched and measured directly by HLC-UV or -MS Mostly GC-amenable analytes

Equally applicable to HPLC and GC analysis

Similar application profile as HS-SPME; however, the NT device is more robust and also has a higher capacity, potentially allowing exhaustive extraction. Also useful in P&T analysis

As in-tube (micro)extraction As in-tube (micro)extraction

Uses not restricted to liquid-phase separation; the name suggests preferential use in conjunction with GC for volatile compounds continued

Analytical Techniques for the Determination of Organic and Organometallic Analytes

TABLE 13.2 Acronym SBSE

SDE

323

(continued) Name of the Method Stir-bar sorptive extraction

Single-drop extraction SDME Single-drop microextraction SME Solvent microextraction Sol-gel CME Sol-gel capillary microextraction Sol-gel OTME Sol-gel opentubular microextraction SPDE Solid-phase dynamic extraction SPME Solid-phase microextraction

Principle/Characteristics PDMS-coated stir bar used for direct or HS extraction and agitation of the sample. More efficient for analytes less hydrophobic than SPME owing to the larger phase ratio Analytes are thermally desorbed in a dedicated desorption unit (for GC) or eluted with solvent (for GC or LC) As LPME

Application(s) Organic compounds that are less hydrophobic to provide good recovery with SPME

As LPME As LPME Capillary microextraction with sol-gel coating Sol-gel pen tubular microextraction with sol-gel coating

Polymer-coated fused silica, polymer, or metal fiber that enriches analytes during exposure to the solid, liquid, or gaseous sample. Analytes are desorbed either thermally (in the GC injection port) or with solvent (for HPLC in a dedicated injector)

Typically for the enrichment of more polar analytes Typically for the enrichment of more polar analytes

Wide range of applications owing to the great variety of commercially available polar to apolar fiber coatings and film thicknesses

On-line SPE is the most elegant, but at the same time the most difficult enrichment technique to implement. On-line SPE-GC requires a dedicated interface that allows the introduction of the large solvent volume needed for the elution of the SPE cartridge. For on-line SPE-HPLC, which can be performed with simple valve-switching systems as well as with dedicated instrumentation (Figure 13.10), a number of restrictions have to be taken into consideration. Firstly, the sorbent trap must be small enough and designed in such a way that it minimizes peak broadening. This typically calls for enrichment columns of 2 mm ID or less and 1 cm in length, filled with less than 20 mg of sorbent material. As a consequence, breakthrough volumes must be carefully determined for the target analytes, since the amount of sorbent is significantly less than for off-line SPE cartridges (with typically 500–1000 mg for silica-based materials).116 Secondly, elution must be accomplished in as narrow a zone as possible, which equates to the smallest possible eluent volume. This can be achieved by various means, such as elution with a high-organic-content eluent, an increase in temperature, elution in backflush mode, or a combination of these factors. In particular, elution with a high-organic-content eluent is critical because the third point of consideration regarding on-line SPE is that the analytes should be refocused at the head of the analytical column to yield sharp peaks. Chromatographic common sense requires that the analytical column should have a stronger retention than the SPE enrichment cartridge. In practice, however, the SPE cartridge is filled with a sorbent material that has the same or an even larger retention than the stationary phase of the analytical column. In order to avoid excessive peak broadening, the (strong) elution solvent must be mixed with a weaker eluent after leaving the SPE cartridge in order to reduce the

324

Analytical Measurements in Aquatic Environments (a) Transfer

Sample fractionation 1

Separation/detection

2

3 7 5

6

1–2. Pumps 3. Autosampler 4. SPE column

5. Analytical column 6. Detector 7. Six-port valve 23912

(b)

4 2

3

1

4

V3

5

6 1

3

V2

5

V1 3

3 N2

gas

SVE

OCI

SDU 2 Syringe pump MSD Analytical column

Retaining precolumn

Retention gap

FIGURE 13.10 Generic setup for (a) on-line SPE-HPLC implemented with a simple valve-switching system (G. Maio, R. Morello, F. Arnold, and K.-S. Boos, Analysis of Antimycotic Drugs in Biofluids by On-Line SPE-LC; Application note LPN 1859-01 06/06; Diones Corporation, Sunnyvale, CA 94088-3603; Figure 2, p. 1, 2006. With permission.) and for (b) on-line SPE-GC implemented with a large volume injector with a solvent venting option.

elution strength of the mobile phase and to allow for a refocusing of the analytes at the analytical column head. Once these issues are resolved, on-line SPE does provide a highly sensitive method for the analysis of environmental contaminants such as estrogens,117 pharmaceuticals,118 and pesticides119 at the trace level. The high sensitivity is a consequence of the fact that the complete eluate is transferred to the chromatographic system and analyzed, and not merely a small fraction of it (typically 0.1–1%), as is the case with off-line SPE techniques. While the above-described sorbents are essentially nonspecific and designed to allow extraction of a wide range of analytes, there are also sorbent phases that are selective toward individual analytes, or at least classes of analytes. These are immunoaffinity (IA) sorbents and molecularly imprinted polymers (MIPs). In the first case, antibodies are immobilized on the solid support used for extraction, and the selective (in the ideal case: specific) biochemical interactions allow an antigen to bind selectively to the antibody, whereas the other sample constituents are not retained and

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can be washed out. Elution of the analyte(s) is achieved with an eluent that temporarily weakens the antigen–antibody interaction or that competes with the analyte for the binding sites.120,121 MIPs, on the other hand, represent an interesting and economic alternative to IA sorbents in view of the tedious and sometimes difficult preparation of the antibodies required, their limited availability, and significant cost.122,123 MIPs are polymer-based sorbents containing cavities introduced during the synthesis that have a very high affinity for the analyte with which they have been “imprinted.” In comparison to IA sorbents they have a significantly lower affinity for the analyte, but can normally be produced faster, more easily, and at a lower cost than IA sorbents. Already commercially available, they hold great promise for environmental analysis.

13.2.5

ANALYTE DERIVATIZATION

Analyte derivatization is commonplace, particularly for chromatographic separation. Derivatization serves mainly three purposes in this context.124 • It leads to a better separation of the analyte. • It improves the detectability of the analyte. • In the case of GC, it also makes less volatile or thermally labile analytes amenable to GC separation. In the ideal case, all the three objectives can be combined. Common examples are the derivatization of polar or ionic analytes for GC. In the case of organic analytes, molecules with active H atoms have to be derivatized in order to prevent the formation of hydrogen bonds between analyte molecules, which reduces their volatility or may even lead to thermal decomposition before volatilization. In the case of ionic organometallic analytes, derivatization may involve, for example, hydridization or alkylation, so that the ionic species can be transformed into neutral and thus volatile ones. The improvement of detectability through derivatization may be due to improved analyte peak shape, but more importantly is due to the introductions of atoms (tags) that enhance the detectability of the derivatized analyte. Common examples are the introduction of a large number of halogen atoms when alcohols or amines are derivatized by means of perfluorinated or perchlorinated acyl chlorides or anhydrides. The resulting perfluoro- or perchloro-carboxylic acid derivatives can be detected by electron-capture detection with very high sensitivity and good selectivity. More exotic, but equally useful are elemental tags other than halogens. One example is the derivatization of alcohols, phenols, thiols, or amines by ferrocene carboxylic acid in order to introduce Fe into the molecule, which can then be detected by GC/AED with unique selectivity and sensitivity.125 Although derivatization is considered primarily for gas chromatographic analysis, it may be equally important in LC (and CE) to ensure or enhance fluorescence detection.124 Even for mass spectrometric detection, derivatization may improve detectability in that derivatives of higher molecular weight are formed, which can then be detected in a mass range with less chemical interference. Derivatization may also be necessary as a means of preconcentrating very polar analytes, such as the herbicide glyphosate and its metabolite aminomethylphosphonic acid (AMPA), which are otherwise too polar to be retained on an SPE cartridge.126 A vast number of derivatization reactions and reagents can be classified into the following groups: • Esterification reagents (e.g., MeOH/HCl) for acidic compounds • Acylation reagents (e.g., trifluoroacetic acid anhydride) for amines and alcohols • Silylation reagents (e.g., N,O-bis(trimethylsilyl)trifluoroacetamide, BSTFA) for compounds with acidic protons • Hydride reagents (e.g., NaBH4) for hydride-forming elements and compounds • Alkylation reagents (e.g., Grignard reagents) for ionic organoelement species

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x

MBT TeEL TEL

50 0 2

3

Carbon 248

TePrL

TML

Counts

200

4

5 6 Retention time

TPT TCYT

100

250

DPT

150

DBT TBT TeBT MPT

TPrT

300

Tin 271 Lead 261 7

8 min

FIGURE 13.11 Element-specific GC-AED chromatograms of simultaneously detected propylated derivatives of OT and organolead compounds in a spiked buffer solution (conc. ~1 μg/L as tin or lead). Abbreviations: TML, trimethyllead, TeEL, tetraethyllead, TEL, triethyllead, TePrT, tetrapropyllead; TPrT, tripropyltin; MBT, monobutyltin; DBT, dibutyltin; TBT, tributyltin; TeBT, tetrabutyltin; MPT, monophenyltin; DPT, diphenyltin; TPT, triphenyltin; TCyT, tricyclohexyltin; X, unidentified OT substance as their propyl derivatives. (From Louter et al. 2005. J. Chromatogr. A 725: 67–83. With permission.)

Analyte derivatization has been the subject of a large number of books, book chapters, and reviews.5,127-133 The gas chromatographic analysis of organometallic species typically requires the transformation of the ionic species into alkylated, arylated, or hydride derivatives.6,134 Grignard reagents have long been used for this task and provide high derivatization yields and robust methods. But they do require a nonaqueous medium, as solvent exchange is necessary prior to the derivatization reaction, and this adds at least one further step to the analytical procedure. For this reason, NaBH4 (for hydridization) and NaBEt4 or NaBPr4 reagents have become increasingly popular as they can be used directly in the aqueous phase,135 although they require a buffered reaction medium and are more susceptible to matrix interferences (Figure 13.11). In the case of OT compound analysis in water samples, the German standard DIN EN ISO 17353136 (formerly DIN 38407-F13)137 suggests the use of a surrogate standard for each substitution stage of the alkyl/aryltin chlorides (R xSnCl4-x) to compensate for fluctuating derivatization yields. The derivatized organometallic species are then extracted into a suitable solvent (or by SPME) and determined by GC/MS, GC/AED, or gas chromatography with flame photometric detection (GC/FPD). In an effort to bypass the crucial derivatization step, liquid chromatographic methods have also been developed for the determination of organometallic compounds.138 In the RP mode of HPLC separation, however, chromatographic resolution is far inferior to GC; moreover, detection is problematic, as the relevant alkylelement species do not absorb in the accessible UV/VIS range and so still have to be derivatized, or be registered by mass spectrometric detectors.

13.2.6

NONCHROMATOGRAPHIC TECHNIQUES

In typical cases the complexity of water samples requires chromatographic separation. In a few instances, however, techniques other than chromatographic, electrophoretic or hyphenated ones are used to determine organic pollutants in the hydrosphere. Many of these relate to the determination of groups of compounds rather than individual compounds, for which the selectivity of the determination method would not be sufficient. Important examples are the determination of organohalogen compounds after adsorption, extraction, or purging from water samples (AOX/EOX/POX).139 After the initial preconcentration step, the organohalogen compounds are combusted, and the halogenide

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thus formed is collected in a buffer solution in which it is coulometrically titrated. Since this sum parameter does not distinguish the different organohalogen compounds, it can only give a rough estimate of the potential hazard posed by the sample. However, in the case of water samples with a relatively uniform composition (e.g., pulp or paper mill effluents), it may provide a good indication of the relative level of organohalogen compound pollution. Likewise, the “phenol index” (based on the color-forming reaction of phenols with 4-aminoantipyrine and photometric measurement at 460 nm) is a widely accepted estimate of the total phenol concentration in water samples, although it is hampered in its interpretability by the fact that different phenols have largely different absorption coefficients at the detection wavelength, and some substituted phenols do not react to the same extent.140 Many of these techniques are implemented in the form of flow injection analysis (FIA) methods. This allows for high-throughput, automated analysis with the possibility of integrating sample preparation in the automated procedure.141,142 Sensors further extend the repertoire of measurement techniques for organic pollutants in the aquatic environment. Although there is still some debate about the exact definition of a sensor system, we can in this context consider a sensor to be a device capable of producing a continuous and reversible response to a single target analyte or a group of them. These characteristics make sensor systems particularly suitable for applications in situations with rapidly changing concentration profiles, such as the effluent line of a factory. A multitude of sensing principles is available (Table 13.3), of which electrochemical and optical ones are the most important.143,144 The underlying chemical reaction can be chemical or, taking advantage of the significantly higher selectivity, biochemical. In the latter case, immobilized enzymes catalyze a specific reaction whose products are detected, for example, by electrochemical or optical measurements; alternatively, antibodies are immobilized to induce a specific immunological reaction with the specific antigen, or DNA serves as a biorecognition element.145,146 On the basis of the biorecognition principle, biosensors are classified as immunochemical, enzymatic, nonenzymatic receptor, whole-cell, and DNA. Biosensors can also be classified according to the type of signal transduction: A transducer converts

TABLE 13.3 Overview of Sensor Techniques Applicable to Organic and Related Analytes and Analyte Classes Compound Metals and metal species Oils/fuels/solvents BOD COD TOC Toxicity DO SS/turbidity Conductivity Total ion concentration/TDS pH Algae/chlorophyll

Techniques Voltammetry, color chemistry, and photometry UV fluorescence, UV photometry, electromagnetic absorption, optical scattering and reflection, capacitive, vapor purging, and VOC gas sensor Bacterial biosensor, biomass oxygen consumption Thermal/chemical oxidation and IR-based CO2 detection, ozone oxidation/consumption, UV/visible spectrometry (inferential method) Oxidation and IR-based CO2 detection, UV/visible spectrometry (inferential) Bacterial oxygen consumption, algal fluorescence, microbial respiration inhibition Clark electrode, fluorescence quenching IR and visible light scattering, optical absorption Current flow between two electrodes Conductivity sensor Glass electrode UV fluorescence

Source: Modified from Bogue, R. 2008. Sens. Rev. 28: 275–282. Notes: BOD, biological oxygen demand; COD, chemical oxygen demand; DO, dissolved oxygen; SS, suspended solids; TDS, total dissolved solids; TOC, total organic carbon; VOC, volatile organic compounds.

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TABLE 13.4 Comparative Features of On-Line SPE-LC-MS Methods versus Biosensors for Environmental Analysis On-Line SPE-LC-MS Comparatively higher sample volumes of water are necessary Matrix effects; ionic suppression; or enhancement in MS spectrometry Preconcentration of the sample necessary (SPE) Multiresidue analysis Automatization and minimal sample handling Direct and fast elution of the sample after preconcentration; minimal degradation No biological stability restrictions Determination of chemical composition Compound selectivity with the use of specific sorbents (MIPs and immunosorbents) Minimal consumption of organic solvents (elution with LC mobile phase) Generation of organic solvent waste Short analysis time and high throughput Limited portability. Confined to the laboratory Applicable to early-warning and on-site monitoring Qualified personnel required Equipment expensive

Biosensors Small sample volumes are sufficient to obtain satisfactory sensitivity Matrix effects variable, depending on biorecognition principle and transduction element Direct analysis of the sample. Minimal sample preparation Limited multianalyte determination Possible automatization of the system Direct analysis after sampling is possible. Minimal degradation Low biological material stability Determination of biological effect and of bioavailable pollutant content Compound selectivity with the use of a specific biological recognition element Consumption of organic solvents avoided. Direct analysis of contaminants in water Minimal, noncontaminating waste Faster analysis; real-time detection and high throughput Availability of portable biosensor systems Applicable to early-warning and on-site monitoring Nonqualified personnel required; user-friendly Equipment cost-effective

Source: Adapted from Rodriguez-Mozaz et al. 2007. J. Chromatogr. A 1152: 97–115.

the biochemical signal resulting from the interaction of an analyte with a biological component into an electronic signal. Physical transducers include electrochemical, spectroscopic, thermal, piezoelectric, and surface wave devices. Table 13.4 lists the advantages of biosensors over on-line SPE-LC with MS detection. In contrast to biosensors, biotests for monitoring water quality make use of bacteria, microorganisms, or higher organisms and register their physiological response to exposure to a potentially hazardous sample. Typical parameters monitored are fluorescence/bioluminescence, respiratory rate, and vitality/mobility.147-149 Biotests have the same kinds of advantages as biosensors for the analysis of water samples. The most significant difference between the two is that the latter typically respond to single compounds, or at least, to a defined class of compounds, whereas the former indicate the overall effect on an organism. Only under very well controlled conditions can the effect be related directly to the concentration of a single chemical in the matrix. Frequently, on the other hand, it is the potential hazard (bioeffect) of a water sample that is to be assessed, rather than the concentrations of all its constituents determined. More recently, biotests have been coupled with chromatographic techniques in order to combine the separation/identification capabilities of hyphenated techniques with the assessment of biological effects. In such experimental setups, which typically involve the splitting of the HPLC effluent between a (mass) spectrometric detector and a flow that is directed to a modified biotest, it is possible to identify compounds and in near real time also to assess the potential hazard posed by this compound (Figure 13.12).150,151

Analytical Techniques for the Determination of Organic and Organometallic Analytes

329

Mass spectrometric detection Affinity binding (chromatography) of ligands Elution and separation of ligands

FIGURE 13.12 System for the bioeffect-related analysis of endocrine disrupting chemicals. (Modified from Seifert et al. 1999. Fresenius J. Anal. Chem. 363: 767–770. With permission.)

13.3

APPLICATIONS TO DIFFERENT CLASSES OF POLLUTANTS

In the first part of this chapter we discussed the general analytical approaches and techniques for the analysis of organic and organometallic pollutants. Now we will take a brief look at the individual classes of relevant compounds and illustrate the discussion with some selected examples; given the limited scope of this chapter, it is impossible to cover the entire field of organic and organometallic analysis in a comprehensive manner. As a justification of our selection of analytes, we will consider a recent study in which waters from 139 streams in the United States were analyzed for a wide range of contaminants.152,153 It revealed that the highest concentrations were found for detergent metabolites, plasticizers, and steroids, although the concentrations were significantly lower than 1 μg/L. The compound classes detected most frequently were steroids, insect repellents, caffeine, triclosan, tri-(2-chloroethyl-)phosphate (a fire retardant), and the detergent metabolite 4-nonylphenol. This is important because both steroids and detergent metabolites are on the list of endocrine disrupting compounds (EDCs). Moreover, nonylphenols (NPs) and octylphenols (OPs), the degradation products of the widely used alkylphenol ethoxylate (APEO) surfactants, have been listed as priority hazardous substances in the European Water Framework Directive.154 Also in European countries, awareness of the contamination of river and surface waters with these so-called emerging pollutants has increased in recent years.155-157 The first results of a similar monitoring program, initiated by the German Ministry of the Environment, show the presence of pharmaceutical compounds at levels >10 ng/L in 39 out of 105 ground water samples.158 Among pharmaceuticals, antibiotics are the substances that are probably giving the greatest cause for concern, in view of the possible resistance of environmental microorganisms to them.

13.3.1

SOLVENTS AND VOLATILE COMPOUNDS

Analytical methods for the analysis of volatile compounds in the environment have been extensively reviewed.85,87,159,160 The volatility of this class of compounds—industrial solvents, emissions from the petrochemical industry and from combustion engines—suggests that GC should be used for their determination. Solvent-free sample preparation techniques, such as P&T (dynamic HS), static HS, and SPME or SBSE, in which the analytes are isolated from the aqueous matrix and simultaneously preconcentrated, are preferred. They also have the advantage that extraction solvents that could interfere with early-eluting, volatile analytes are avoided. If solvent extraction of volatile compounds

330

Analytical Measurements in Aquatic Environments

from water samples is inevitable, a late-eluting solvent could be chosen as an alternative to prevent the solvent from “blackening out” the portion of the chromatogram in which the volatile compounds (e.g., methyl tert-butyl ether (MTBE) or trihalomethanes) elute. Depending on the detector used and the sample preparation/preconcentration technique applied, detection limits in the low ng/L level are easily achievable with sample volumes of £5 mL.161 Despite its simplicity, direct aqueous injection for the determination of trihalomethanes and other volatile compounds is no longer used because of its inferior detection limits.162 However, membrane-based sample introduction techniques have been successfully used for this task.98,99

13.3.2

PESTICIDES

The increased use of pesticides (herbicides, fungicides, and insecticides) in intensive farming has led to a growing need to monitor these compounds and their metabolites in the hydrosphere, into which they easily leach after application. An enormous body of work has thus been performed over the last three decades to develop, improve, and validate analytical methods, based mostly on GC or LC, and more rarely on other chromatographic or electrophoretic techniques.163-167 The inhomogeneity of this class of chemicals makes it impossible to design one method to suit all of them. Clearly, GC- and especially GC-MS-based methods are very important for the more volatile pesticides, such as organochlorine and organophosphorus pesticides, pyrethroids, and triazines, to mention but a few. Some analytes that are not sufficiently volatile can be determined after derivatization (e.g., chlorophenoxyacid herbicides after esterification) or decomposition (e.g., dithiocarbamate fungicides that decompose to form CS2, which can be detected with very good sensitivity). Since MS detection has essentially supplanted all other detectors for gas chromatographic trace analysis, this has also paved the way for multiresidue methods. With current instrumentation, it is easy to integrate the determinations of from tens to more than one hundred pesticides into one chromatographic run.168-170 Considering the likelihood of co-elution or matrix interference, additional identification or confirmation power is obtained by using either high mass resolution (with sector-field or TOF instruments), low-energy fragmentation of selected precursor ions (available with quadrupole MS/MS or ion trap instruments), or retention time locking (RTL). In this last technique, retention times are used as an additional parameter in the library search for pesticides. This requires an exceptional retention time stability, which is achieved by adjusting the actual retention times by the use of a lock compound.171 The high data acquisition rate of modern TOF instruments allows, already after 1D-GC separation, the deconvolution of overlapping peaks by suitable mathematical procedures. This assumes that the overlapping peaks are not completely co-eluting, and that their spectra are sufficiently different (Figure 13.13). 2D-GC-MS provides significantly higher chromatographic resolution, which, in many cases, leads to peaks that are completely resolved from their neighbors. Nowadays, however, the majority of multiresidue methods are performed with LC/MS. This alleviates the restrictions resulting from the polarity or nonvolatility of the analytes. Because of the lower separation capability of LC in comparison to GC, such multiresidue methods are only successful with triple quadrupole or other hybrid mass spectrometers that offer enhanced selectivity.67,172,173

13.3.3 PHENOLS AND OTHER INDUSTRIAL CONTAMINANTS Phenols are important industrial chemicals, for example, in the production of various plastics and resins, and may leach into surface and ground waters either during production or from the discharged products at landfill sites. Because of their ecological importance and their widespread use, methods for phenols and related compounds (e.g., anilines) were developed already at an early stage. Many of these methods rely on GC (or GC/MS), which normally requires derivatization prior to GC analysis. Standard methods for the derivatization of phenols are silylation, methylation, or acetylation.5 The last mentioned has the advantage that it can be carried out in the aqueous sample directly. The derivatized phenols can thus be extracted more easily and with a higher yield from the aqueous sample by

Analytical Techniques for the Determination of Organic and Organometallic Analytes

3500

404 405

407 408 410 411 412

413 414

3000

65 133 194

2500

Peak true at 388.131s

Peak true at 388.031s 100 1000 500

500

272

500 339

1500

Time (seconds) 386 387 388 389 390 100 65 196 198 102 39 272 170

500

65 135

196

170

225

314

86 125 168

337

337

50 100 150 200 250 300 350 400 450 500

254

50 100 150 200 250 300 350 400 450 500 Caliper at 388.131s 100 1000 500

272

395 448

50 100 150 200 250 300 350 400 450 500 Library hit—pichloram methyl esther 196 1000 500

272

50 100 150 200 250 300 350 400 450 500 Caliper at 388.031s 100 1000

1000

49 86

420 473

65 135 194

196

1000

50 100 150 200 250 300 350 400 450 500 Reference spectrum match 735—heptachlor 100 1000

2000

331

65

196 170

272 337

50 100 150 200 250 300 350 400 450 500

FIGURE 13.13 Left: Part of the GC/TOF-MS chromatogram from the analysis of pesticides (acquired with a Leco Pegasus III TOF MS). Right: Two mass spectra near the peak apex are reported (top), together with the library entries (middle) and the deconvoluted spectra (bottom).

solvent extraction, SPE, or SPME. Furthermore, derivatization may enhance sensitivity for the following reasons: firstly, the improved peak shape leads to a narrower, symmetrical peak resulting in better quantification. Secondly, by way of derivatization, several halogen atoms are introduced into the derivative of one analyte molecule if ECD is used, thereby overproportionally enhancing both sensitivity and selectivity. Many useful reagents exist for the introduction of halogens (e.g., perfluorinated carboxylic acid anhydrides or chlorides), but also other heteroatoms such as iron can be introduced as the “elemental tag” for less common derivatization reagents like ferrocenecarboxylic acid chloride. If this reagent is used for the derivatization of phenols in combination with AED, unmatched selectivity and sensitivity can be achieved.174 In many instances, GC is the preferred separation method for phenols owing to its higher separation power. More recently, however, there has been a shift in favor of LC, and toward LC/MS in particular. This reflects the generally greater availability of this technique as well as its ability to determine underivatized phenols in water samples at ultratrace levels. This technique can be rendered even more sensitive by automated on-line SPE, which enables phenols to be quantitated in water samples even at ppt levels (Figure 13.14).175 Similar considerations also apply to other phenols, such as the EDC bisphenol A145 and anilines.176

13.3.4

SURFACTANTS

Nonionic surfactants represent the largest fraction of surfactants used nowadays. Among these, APEOs and their metabolites (alkylphenols and short ethoxy chain oligomers) are the compounds of greatest environmental concern due to their estrogenic potential. Even if their estrogenic activity appears to be low in comparison to natural estrogens, this is by far offset by the scale at which these compounds are used—some 106 tons/annum, with practically all of these being discharged into sewage and waste water. Despite the relatively high concentrations in waste water, a multistep sample preparation procedure is still required to reduce matrix interferences and to preconcentrate analytes. For aqueous samples, SPE is the technique of preference. With C18 SPE cartridges, extraction yields in excess of 70% have been reported.177 To achieve a preliminary separation, sequential SPE schemes with different sorbent materials may be applied that allow the fractionation of neutral and acidic degradation products.178 The separation of APEOs on an RP column is only successful if there are differences in the hydrophobic part. Homologs with different numbers of ethoxy units co-elute in RP-HPLC. As a result of this co-elution, the chromatograms have a relatively simple structure and the signal intensity is increased. However, quantitation is severely compromised because of the different response

332

Analytical Measurements in Aquatic Environments

(a) 400000 35000 30000 25000 20000 15000 10000 5000 0

4-NP

4-CP 2,4-DNP

5

4-NP

15 2-NP +2-CP

2,4-DNP

PCP

20 4-C-3-MP 2,4-DCP 2,4,6-TCP

25

min

4-CP 2,4-DMP

Ph

Interferences

PCP

Interferences

2-M-4,6-DNP 5

(c) 400000 35000 30000 25000 20000 15000 10000 5000 0

10

Humic substances

4-C-3-MP 2,4-DCP 2,4,6-TCP

2,4-DMP

Ph

2-M-4,6-DNP

(b) 400000 35000 30000 25000 20000 15000 10000 5000 0

2-NP +2-CP

10

15

20

25

min

Humic substances Interferences

5

10

15

20

25

min

FIGURE 13.14 A typical LC-MS chromatogram obtained in the scan mode of a preconcentrated aqueous standard solution (a) and of a preconcentrated spiked river water sample (b), as well as of an unspiked preconcentrated river water sample (c). Peak labels denote: Ph, Phenol; 2,4-DMP, 2,4-dimethylphenol; 2-CP, 2-chlorophenol; 4-CP, 4-chlorophenol; 4-NP, 4-nitrophenol; 2-NP, 2-nitrophenol; 4-C-3-MP, 4-chloro-3-methylphenol; 2,4-DCP, 2,4-dichlorophenol; 2,4-DNP, 2,4-dinitrophenol; 2,4,6-TCP, 2,4,6-trichlorophenol; 2-M-4,6-DNP, 2-methyl-4,6-dinitrophenol; and PCP, pentachlorophenol. Spike level 1 μg/L; 10 mL preconcentrated.

factors of the oligomers, and also the isobaric interference of the doubly charged ions [M + 2Na]2+ of highly ethoxylated APEOs and the singly charged ions of less ethoxylated APEOs. Separation of nonylphenols takes place in accordance with the number of ethoxy groups. Homologs with the same number of ethoxy groups but different alkyl substituents co-elute. A prominent example is the separation of octylphenol ethoxylates (OPEO) and nonylphenol ethoxylates (NPEO). Since the mobile phase in NP-HPLC typically consists of one apolar organic solvent or a mixture of them, a polar solvent must be added to enhance ion formation for ESI-MS. Altogether, complete resolution of ethoxylate surfactants requires multidimensional separation, which can be performed on- or off-line by coupling two orthogonal separation mechanisms such as NP- and RP-HPLC, SEC and RP-HPLC, or RP-HPLC and HILIC.179 In LC-MS analysis of ethoxylates, ESI used to be the preferred method of ionization due to its higher sensitivity, particularly for APEOs. Under these conditions, APEOs display a marked tendency to form sodium adduct ions [M + Na] +, predominantly with long-chain APEOs, but less frequently with shorter-ethoxy chain APEOs. This variable response of the homologs, depending on their ethoxy chain length, and the reduced fragmentation observed under CID conditions, is why the formation of ammonium adduct ions, being more suitable for MRM detection, is now preferred (Figure 13.15). There are numerous reports on the use of ESI-MS after NP or RP separation for the determination of ethoxylates in environmental samples, providing both qualitative and quantitative information. For lack of appropriate reference substances, analysis of their metabolites is more difficult. As an example, mono- and dicarboxylated metabolites are formed in the biodegradation of APEOs, leading respectively to alkylphenol ethoxy carboxylic acids (APECs) and carboxy alkylphenol ethoxy carboxylic acids (CAPEC), which are detectable in negative ion-ESI-MS. Quantitation is tentatively based on MS/MS spectra, which exhibit intensive signals for APECs at m/z 219 (for nonylphenol ethoxylate carboxylic acids, NPEC) and m/z 205 (for octylphenol ethoxylate carboxylic

Analytical Techniques for the Determination of Organic and Organometallic Analytes

333

(a) 100

336

790

Rel. intensity (%)

60 40

E+04 1.95

658

512

80 182 279

20 (b) 100

200

400

600

800

182

80 60 40

264 279 295

20 200

414 502 400

590 600 m/z

678

1000 E+03 7.64

756 800

1000

FIGURE 13.15 Flow injection–APCI-MS(+)spectra for waste water samples. (a) WWTP inflow and (b) conventional WWTP effluent after C18 SPE; eluent and methanol. Positive APCI. (Redrawn from Li et al. 2000. J. Chromatogr. A 889: 155–176. With permission.)

acids, OPECs).180,181 GC and GC/MS, possibly following derivatization, are useful techniques for both the parent ethoxylates and their degradation compounds, and they offer even better opportunities for identification and quantitation.182

13.3.5

SULFONATES

Sulfonates are the most important group of anionic surfactants and probably the most widely used household detergents. Among these, the best known group is that of the linear alkylbenzene sulfonates (LAS), which are commonly analyzed by RP-HPLC-negative ion-ESI-MS methods.183,184 This class of compounds can also be determined by GC techniques after suitable derivatization (e.g., by esterification with alkylation reagents).185 Sulfophenyl carboxylates (SPCs) are the degradation products of LAS, but they are too polar to allow successful LC separation. Instead, their chromatographic separation requires IC or ion-pair RP with triethylamine or tetraethylammonium acetate.186 More recently, perfluorinated sulfonates, such as perfluorooctane sulfonate (PFOS), have attracted attention because of their resistance to biodegradation and the practically ubiquitous exposure of humans and wildlife to these compounds. From the analytical point of view, these compounds can also be determined by LC-MS with negative ion-ESI187 or by GC/MS after derivatization.188 The importance and broad scope of this topic are reflected in numerous reviews and books covering analysis of ionic and nonionic surfactants189-191

13.3.6

ESTROGENIC SUBSTANCES

The increased use of contraceptive pills worldwide has made the release and the elevated levels of estrogens and steroid sex hormones consequently found in sewage and surface waters an important issue. Analytical methods for this group of compounds are well developed and have been extensively reviewed.192-195 They are based either on GC/MS after derivatization or on LC/MS. In order to achieve the sensitivity and selectivity required for the analysis of estrogens in waste water samples, triple quadrupole instruments are typically employed, and sample preparation—normally based on SPE enrichment and cleanup—must be well designed. Rigid quality control has to be applied to ensure the correctness of results in the complex sample matrix; it has to take into account the stability of

334

Analytical Measurements in Aquatic Environments

chromatographic retention time and mass spectrometric peak intensity ratios, and make use of isotopically labeled standards where available. As is the case with other organic compounds in the hydrosphere, conjugated forms of the steroid hormones (e.g., sulfates or glucuronides) should also be taken into account in their determination.196

13.3.7

PHARMACEUTICALS

The occurrence of pharmaceuticals in waste water, sewage, surface, and ground water—and in rare cases also in drinking water—has become a very important matter as a result of the increased consumption of these compounds. About 3000 different substances with widely differing properties and structures are used today for human and veterinary health care.197 Many pharmaceutical compounds and metabolites are polar, which makes LC and in particular LC/MS the method of choice for their analysis. Again, the selectivity and sensitivity of the analytical method depend principally on the sample preparation method, which usually involves SPE, using either “classical” RP materials or more modern polymeric materials that extract analytes over a wide range of polarities, based on the presence of different functional groups in the material (“mixed mode” SPE). Like the multiresidue methods for pesticide analysis, such methods have also been developed for pharmaceutical residues with the aim of determining one or several classes of pharmaceutical compounds in water samples.198-200 Particularly in the highly complex samples stemming from WWTP effluents, the structural elucidation capabilities of (single quadrupole-)LC/MS are limited. In these cases, the use of triple quadrupole-LC/MS (LC/MS/MS) or of LC with hybrid mass spectrometric detectors becomes indispensable. These are capable of providing second- or higher-order mass spectra, and/or high mass resolution, from which additional structural information can be generated and increased selectivity attained (Figure 13.16).201,202 Table 13.5 gives an overview of typical analytical procedures for important pharmaceutical compounds. Among the groups of compounds listed there, antibiotics are probably giving the greatest cause for alarm, as their occurrence in the environment can induce resistance in certain microorganisms to these compounds. X-ray contrast and magnetic resonance imaging (MRI) agents are a further class of compounds whose environmental effects cannot yet be clearly foreseen.

13.3.8

PERSONAL CARE AND COSMETIC PRODUCTS (PCCPS)

PCCPs constitute a broad class of compounds used for human and veterinary applications (e.g., food additives, sunscreens, insect repellents, body lotions, shampoos, and deodorants).203,204 Some of these compounds are on the list of high production volume chemicals. The annual production of PCCPs in Germany, for example, exceeded 550,000 tons in the early 1990s.205 These compounds are applied externally as skin, hair, and dental care products or soap additives, or they are directly or indirectly ingested, transformed in the body or not, and finally excreted as a combination of unaltered PCCPs and metabolites. Both parent compounds and their metabolites enter the aquatic environment, mainly through municipal WWTPs, in ppt to ppb concentrations. An alternative route to the hydrosphere is when PCCPs are released directly into surface waters from the skin during swimming or bathing; variable concentrations of these compounds are therefore detected in surface, ground, and coastal waters. Moreover, other degradation intermediates of these compounds may form as a result of biotic or abiotic processes in WWTPs or surface waters:206 The analysis of PCCPs follows different strategies, depending on the chemical nature of the compounds investigated. After SPE or LLE for preconcentration and cleanup, the analytes are separated and determined by GC or LC with MS detection. Given the complexity of samples, two-dimensional chromatography appears to be an appropriate way of improving chromatographic resolution, while the use of MS/MS or TOF-MS brings additional spectrometric information that allows structural confirmation or elucidation.202,206

Analytical Techniques for the Determination of Organic and Organometallic Analytes

1: TOF MS ES+

3.97 100

%

237

1 Da window S/N:PtP=1.53 5.78

3.33

0.32 0.64 1.10

0

2.55 2.0

4.63

5.64

6.62 6.52

4.0 Time (min)

7.44 7.96

7.10

6.0

100 mDa window S/N:PtP = 8.06

1:TOF MS ES+ 237.10 0.10 Da

6.60 3.35

% 0.64 0

1.87

2.25 2.25 2.0

3.71 4.03

4.85 5.17

4.0 Time (min)

6.36

6.72

7.44

6.0

8.38 8.71

8.0

1:TOF MS ES+ 237.103 0.02Da

5.78 100

8.81

8.0

5.78 100

335

20 mDa window S/N:PtP = 115.25

% 7.22

3.21 0

2.0

4.0 Time (min)

6.0

8.55 8.0

FIGURE 13.16 Enhanced selectivity of UPLC–TOF–MS analysis of the pharmaceutical compound carbamazepine (m/z 237.103) in an urban wastewater sample, as a result of varying mass windows in the reconstruction ion chromatogram. (Reprinted from Petrovic et al. 2006. J. Chromatogr. A 1124: 68–81. With permission.)

13.3.9

ORGANOMETALLIC SPECIES

13.3.9.1 Organotin (OT) Compounds In the present context, we shall restrict our discussion of the determination of elemental species to OT compounds and other organic compounds of group IV elements (Pb and Ge) and Se, since the speciation of other elements is covered in Chapter 7. In the aquatic environment, organometallic speciation is of particular relevance for OT compounds. These, and particularly tributyltin, have been intensively used for decades as the bioactive ingredient for antifouling paints applied to ships’ hulls. Tributyltin compounds are highly toxic to molluscs, thereby preventing the growth of barnacles and shells on the hull. The surface roughness of the hull is an important factor affecting the cruising speed of sea-going vessels and their fuel consumption in a given route. It is thus of the greatest economic importance to prevent the growth of crustacea on hulls, and this is achieved by the controlled release of OT compounds from the

336

Analytical Measurements in Aquatic Environments

TABLE 13.5 Examples of Analytical Methods for Different Pharmaceutical Compound Classes Class Lipid regulators Antiphlogistics Betablockers

b2-Sympathomimetics Psychiatric drug Antibiotics

X-ray contrast media

Estrogens

Compounds

Extraction method

Separation

Detection

Clofibric acid, bezafibrate Diclofenac, ibuprofen, naproxen Metoprolol, propanolol, betaxolol Terbutalin, salbutamol Diazepam

SPE, LiChrolut RP-18 SPE, LiChrolut EN, Oasis HLB SPE, PPL Bond Elut

Genesis C18 (150 × 2.1 mm, 4 μm) LiChrospher C18 (125 × 3 mm, 5 μm) Nucleosil C18 (250 × 2 mm, 3 μm)

Negative ion-ESIMS-MS (MRM) Negative ionESI-MS Positive ion-ESIMS-MS

SPE

Clarithromycin, sulfamethoxazol trimethoprim, ciprofloxacin

Tandem SPE Oasis HLB/MCX, mixed phase MPC

Positive ion-ESIMS-MS (MRM) Positive ion-ESIMS-MS (MRM) Positive ion-ESI-MS

Iopamidol, iopromide, iomeprol Estradiol, 17b- estrone

SPE, Isolute ENV+

LiChrospher C18 (125 × 3 mm, 5 μm) LiChrospher RP-18 (125 × 3 mm, 5 μm) Luna C8 (100 × 4.6 mm, 3 μm) Luna RP-18 (150 × 2 mm, 3 μm) Nucleosil RP-18 (200 × 2 mm, 5 μm) LiChrospher RP-18 (125 × 3 mm, 5 μm) Purospher RP-18 (55 × 2 mm, 3 μm) LiChrospher RP-18 (250 × 4 mm, 5 μm)

Negative ion-ESI-ITMS (SIM), ESI-MS (SIM)

SPE, Isolute C18

SPE, C18

Positive ion-APCIMS-MS, Positive ion-ESIMS-MS Positive ion-ESIMS-MS (MRM)

Source: Modified after Zwiener, C. and F.H. Frimmel. 2004. Anal. Bioanal Chem. 378: 851–861.

antifouling paint.207,208 However, once released into the aquatic environment, OT compounds also affect nontarget organisms such as oysters or dogwhelks (a species of marine snail). It was actually the observation of malformations in oysters produced at oyster farms in southern France (in the vicinity of which there was a high intensity of yachting activities with OT-painted boats) that focused public attention on the undesirable and most alarming side effects of OT compounds. Later, the phenomenon of imposex (the induction of male sexual organs in female animals) was also observed, as a result of which the female gastropods become infertile. These fi ndings indicated that OT compounds—mainly tributyltin and triphenyltin—represent a great environmental hazard and induce endocrine disrupting effects. As a consequence, numerous environmental studies were performed to assess the actual state of pollution209 and methods developed for the analysis of OT compounds in aqueous, sediment, sludge, and biota samples.6,210,211 It very quickly became evident that, owing to the hydrophobicity of trisubstituted OT compounds, measurements of their concentrations in the aqueous phase would only produce meaningful data in the case of recent OT input into the hydrosphere, and in the absence of suspended matter or biota to which the OT compounds could be adsorbed. In the case of biota (particularly fish and mussels) the high concentrations in relation to the aqueous concentrations of OT compounds are explained not only by partitioning between the two phases but also by bioamplification, as these animals are higher members of the trophic chain. The analysis of OT compounds from these matrices is clearly more demanding than that from aqueous samples because of the interferences in the sample preparation (extraction and derivatization) or determination steps. In this case, the sample preparation strategy has to be appropriately designed

Analytical Techniques for the Determination of Organic and Organometallic Analytes

337

so as to reduce interferences from the matrix. This is, for example, achieved by silica-column cleanup or by SEC of the extracts. The typical analytical procedure for OT compound analysis involves a sample digestion and/or extraction step. In the case of biota (fish or mussel tissue), this is alternatively done by using acidic organic phases (e.g., methanolic HCl or AcOH/MeOH), which do not achieve complete digestion of the sample material, or by alkaline digestion with methanolic NaOH or Bu4NOH that completely solubilizes the sample tissue and releases the physi- or chemisorbed OT compounds.211 For inorganic (sediment and soil) samples, only organic/acidic extractant phases are normally used. For these, and also for the extraction of OT compounds from aqueous samples, complexing agents are added. Acetic acid or the chloride anion from the acid used during extraction may at the same time act as ligands for the OT compounds and enable its transfer to an organic phase (hexane or iso-octane). Transfer to the organic phase (followed by the drying of this phase) is required when derivatization is performed with a Grignard reagent. After partitioning of the reaction mixture with dilute sulfuric acid (to remove the excess of derivatization reagent), the organic phase can be dried again and injected directly into the GC for analysis.6 As an alternative to this route of sample preparation, derivatization with sodium tetraethylborate (NaBEt4) has gained in popularity. In this case, no solvent exchange is required prior to derivatization; instead, this can be performed directly in the aqueous phase buffered to a pH of approximately 4.5.135 The analytes are then extracted with a suitable solvent or by SPME prior to GC analysis. The practicality of this approach makes up for the somewhat lower stability of this method in comparison to Grignard derivatization performed under the optimum conditions of each method. In the early phase of OT speciation analysis, hydride formation of OT compounds was also a common route, and particularly suitable for the analysis of OT compounds in aqueous samples by P&T sample preconcentration.212 Because of the high volatility of OT hydrides and the danger of losses during sample preparation, this procedure is nowadays no longer considered suitable. The derivatized OT compounds can be determined by GC with various detectors. GC with atomic emission detection (GC-AED) is one of the most versatile techniques, combining as it does very good sensitivity and selectivity for OT compound determination. Since this type of instrumentation is available only from one commercial supplier, GC-AED faces strong competition from GC-ICP-MS instruments. These are more expensive and also more demanding in their operation, but are often available in specialist laboratories and can be used for OT compound analysis with a sensitivity of about two orders of magnitude higher. Other instrumental solutions suitable for the routine monitoring of OT compounds at low trace (but perhaps not ultratrace) levels include GC with (pulsed) flame photometric detection [GC-(P)FPD] and GC-MS (Figure 13.17).213 Much in line with the general tendency to use LC-MS for the analysis of compounds, which otherwise would require derivatization for GC analysis, liquid chromatographic techniques are also used for OT compound analysis.138 In the absence of chromophoric groups, HPLC analysis again requires either derivatization (e.g., fluorescence derivatization)214 or the use of mass spectrometric detection. Molecule-specific mass spectrometric detection has been used successfully for this task,215 but ICP-MS is several orders of magnitude more sensitive; it is thus the technique to be preferred, if available. Moreover, ICP-MS offers better compatibility than does ESI- (or APCI-)MS with separation modes or mobile phase compositions providing good chromatographic resolution (IC or ion-pairing chromatography on RP columns).216 Table 13.6 presents an overview of common separation/detection options for OT compounds and some of their most important characteristics. As a result of the 2003 ban on OT compounds in antifouling paints, the current input of OT compounds into the water column is slowly decreasing.217 However, as there are also other important uses of OT compounds (as fungicides in agriculture, as stabilizers in plastics, as industrial catalysts, and as precursors in organic and inorganic syntheses), they will continue to occur in the aquatic environment, albeit at reduced levels. The lower the concentration of OT compounds in the aqueous phase becomes, the more re-emission from contaminated sludge or sediments by resuspension or re-equilibration has to be considered as a new and long-lasting source of OT compound occurrence in the aquatic environment.218

338 TPrT (ISTD)

Analytical Measurements in Aquatic Environments

60

20

DBT

40 MBT

Signal (counts)

80

GC-AED

TPhT

MPhT TBT

(a)

0 8

75

25

MBT

Signal (mV)

(b) 100

50

10

DBT TPrT (ISTD) MPhT TBT

6

12

14

GC-PFPD TPhT

0 5

7.5 10 Retention time (min)

12.5

FIGURE 13.17 Typical chromatograms obtained from the analysis of a freeze-dried fish reference sample (NIES 11) with GC-MIP-AED (a) and PFPD (b); 2 mL of extract used in (a) and 0.5 mL of extract used in (b). Peak labels denote: MBT, monobutyltin; DBT, dibutyltin; TBT, tributyltin; TPrT (ISTD), tripropyltin (used as internal standard), MPhT, monophenyltin, TPhT, triphenyltin, all as ethylated derivatives. (Redrawn from Aguerre et al. 2001. J. Anal. At. Spectrom. 16: 263–269. With permission.)

TABLE 13.6 Overview of the Individual Steps of Procedures for OT Compound Speciation in Marine Samples (Sediments, Water, and Biota) as Reported in the Literature Extraction

Derivatization

Preconcentration

• Acid and polar solvent – HCl or HBr/MeOH – Acetic acid/MeOH

• Tetraalkylborate reagents – Ethylation – Propylation

• Acid and other (less polar) solvent – HCl/toluene – HCl/diethyl ether – HCl/ethyl acetate • Extraction with apolar solvents + compleing agent – Toluene (HCl) + tropolone – Hexane + DDTC • Basic digestion – TMAH – MeOH/NaOH • PLE (ASE): – Sodium acetate and acetic acid/MeOH • SPE (for aqueous samples)

• Grignard – Pentylation – Propylation – Ethylation

• SPME • Solvent extraction + solvent volume reduction • SPE

Analysis • GC-MS • GC-FPD • GC-PFPD • GC-ICP-MS • GC-MS/MS

• HPLC-ICP-MS • HPLC-ESI/APCI-MS • HPLC-FD

Analytical Techniques for the Determination of Organic and Organometallic Analytes

339

13.3.9.2 Organolead Compounds The main source of organolead compounds in the environment is the tetraalkyllead compounds used as antiknocking agents in leaded gasoline.219 Lead additives have been banned in the industrialized nations, but are still in common use in other parts of the world. These species enter the atmosphere as a result of incomplete combustion or evaporation during the production and distribution of antiknocking agents and leaded gasoline. Once released into the environment, the volatile organolead species can be transported over great distances in the gaseous state, or adsorbed to particles. The originally emitted tetraalkyllead compounds decompose via sequential dealkylation through the tri-, di-, and monosubstituted stages into inorganic lead.220 The toxicity of organolead compounds depends on the actual chemical composition and increases with the number of alkyl groups, thus making speciation of organolead compounds necessary. Commonly used techniques for this purpose are chromatography and hyphenated methods, mostly coupled with element-specific detection, for example, GC-AED,221 GC coupled with atomic absorption detection (GC-AAS),222 or ICP-MS. The last mentioned provides superior sensitivity as well as the possibility of using isotopically labeled standards for quantification and quality control.223 As organolead compounds are typically present in the environment in ionic form, their sample preparation is similar to that of OT compounds: alkylation is normally applied (occasionally also hydridization) to form GC-amenable derivatives of the formula R xPbR¢4-x or R xPbH4-x. Grignard derivatization (with alkyl reagents of various chain lengths) has long been the preferred derivatization technique. Derivatization with NaBEt4 is not feasible because ethyllead compounds are used in addition to methyllead, so that their derivatization with NaBEt4 will render speciation analysis meaningless. As soon as the analogous tetrapropylborate reagent (NaBPr4) became commercially available, the simplified alkylation procedure was readily adopted for the direct derivatization of alkyllead compounds in aqueous samples.135,222 In contrast to OT compounds, organolead compounds were not directly released into the aquatic environment, at least not intentionally. As becomes clear from their profile of usage, however, they entered the water cycle through evaporation from their technical uses, became more water-soluble in the form of ionic compounds that were formed through dealkylation, and were transported over long distances. The analysis of water samples for organolead compound contamination can thus be considered an indicator of anthropogenic activity at the particular location of observation.219 This explains why more often than river or surface water, samples of rainwater or snow from remote locations such as Antarctica are investigated for their organolead content. These concentration profiles clearly reflect the increased technical use of organolead compounds from the 1930s, and their eventual phasing out (at least in large parts of the world) from the early 1980s.224 For the same reason, and because the use as an antiknocking additive to gasoline was the only relevant largescale application of organolead compounds, interest in the speciation analysis of this element has virtually ceased. 13.3.9.3 Organogermanium Compounds The biogeochemistry of germanium is not yet well understood.225,226 Despite its position in the main group IV of the periodic table, which suggests that this element can form many organic compounds, there are actually only a few organogermanium compounds with technical or other relevance, and only two of environmental relevance.227 These two—mono- and dimethylgermanium—have been detected at ultratrace concentrations (i.e., in the low picomolar range) in various waters, including surface, river, and sea water.228 In contrast to OT and organolead compounds, the profiles of these two organogermanium compounds are very conservative, indicating that methylgermanium compounds may be converted on a timescale of 106 years. It is also not understood why, again in contrast to the organoelement compounds of the heavier members of this group, there is no naturally occurring trimethylgermanium. Apparently, the biosynthesis of methylgermanium compounds leads only to the mono- and disubstituted compounds; initial reports of trimethylgermanium detection can

340

Analytical Measurements in Aquatic Environments He in

Ar purge gas in To variac

NaBH4 or Cl–/H+

To graphite furnace atomic absorption spectrometer Silanized glass wool Water trap Reaction (alcohol + dry ice) vessel

Liquid N2 trap

FIGURE 13.18 Typical experimental setup for the (P&T) generation collection and determination of volatile germanium hydrides from water samples after borohydride derivatization.

probably be attributed to analytical artifacts. Analytical methods for organogermanium compounds have not been particularly well investigated, but they follow the same strategy as for other organometallic compounds: the ionic methylgermanium compounds have to be derivatized for GC analysis by alkylation with Grignard or tetraalkylborate reagents, or by hydride formation. Given the fact that germanium compounds are more volatile than their tin or lead homologs, simultaneous matrixseparation and enrichment of the analytes is efficiently performed by P&T analysis.228 In this early example of Ge speciation, the cold trap served simultaneously as a packed analytical column for separating individual methylgermanium species (Figure 13.18). Later, the analytical method was refined in that capillary columns were used for the GC separation. Alternatively, underivatized methylgermanium chlorides (which are sufficiently volatile and relatively stable) were determined directly,229 or after Grignard derivatization.230 Fully alkylated organogermanium compounds show a better recovery owing to their reduced interaction with active sites of the GC system, and also a better peak shape. Following the early work on organogermanium compounds in (sea) water in the 1980s228,231 and some further methodological development in the mid-1990s,229,230,232 which remained without application in the hydrosphere, there appears to have been no recent interest in the speciation analysis of organogermanium compounds in the aquatic environment, which may reflect the low level of hazard believed to be due to these species. 13.3.9.4 Organoselenium Compounds Although not an element of the main group IV of the periodic table, selenium also forms stable organoelement species of some environmental relevance. Whereas selenium may occur in its inorganic compounds in the oxidation states –II, +IV, or +VI, the only stable organoselenium compounds are those of Se(+II). Dimethyl selenide and dimethyl diselenide, and also the trimethylselenonium cation, have been reported in the natural environment.233 The transformation of inorganic Se to the more volatile but less toxic methylated Se species by microbial action is an important link in the biogeochemical cycling of this element. In the presence of biota, the selenoaminoacid and selenomethionine can also occur.234 Dimethyl selenide and dimethyl diselenide are volatile compounds that can be determined by GC with element- or molecule-specific detection. Due to their volatile nature, enrichment and matrix separation by P&T is particularly advantageous.235 To determine the complete speciation of this element, the concentration of the inorganic Se species also has to be determined, which is at least indirectly possible with a modification of this technique: inorganic Se(+IV) (selenite) can be derivatized directly with NaBH4 or NaBEt4 to form SeH2 or Et2Se. While the former species is well known from the determination of (total) selenium by hydride generation-atomic spectrometry (atomic absorption detection (AAS, OES, or ICP-MS), the latter derivative can be

Analytical Techniques for the Determination of Organic and Organometallic Analytes

341

determined separately without interferences236 or together with the dimethyl(di-)selenide species.237 In a further report,238 tetraethylborate derivatization was compared to the derivatization of Se(+IV) by 4,5-dichloro-1,2-phenylenediamine to form the corresponding piazselenol. The analytical figures of merit of the two derivatization schemes compare very well. NeBEt4 derivatization is particularly advantageous since it can be performed directly in the aqueous phase, and is thus more expeditious, particularly when combined with SPME. As a general disadvantage of all these methods, it must be mentioned that only Se(+IV) can be derivatized directly. If Se(+VI) (selenate) is to be determined, it has to be prereduced, for example, with half-concentrated HCl.239 The Se(+VI) concentration can thus be determined from the difference in the signal with and without the preceding reduction step; however, the analytical precision of the determination suffers significantly from this indirect determination and may be inadequate. The determination of organic selenium compounds is done preferably by GC coupled to elementor molecule-specific detectors, such as GC-AED or molecular mass spectrometric detection (GCMS).240 In this case, ICP-MS detection does not yield the improvement in sensitivity otherwise seen, which is due to spectral interferences. Dietz et al.241 have compared the analytical figures of merit of three detector systems for GC (AED, atomic fluorescence spectroscopy (AFS), and ICP-MS), arriving at the conclusion that GC-AED is the most sensitive and most practical

100

(SeM × H)*

m/z 198

8.4 × 104 ions/sec

100 80 60 40 20 0 190 192

194

196 m/z

198

200

202

50

0 100

100 80 60

(SeCM × H)* Relative abundance (%)

9.9 × 104 ions/sec

m/z 247

40 20 0 238 240 242 244 246 248 250 252 254

50

m/z

0 100

m/z 339 (SeC × H)*

100 80 60

5.4 × 104 ions/sec

40

50

20 0 328 330

332

6

8

334 m/z

336

338

340

0 0

2

4

10

12

14 16 Minutes

18

20

22

24

26

28

FIGURE 13.19 CE/ESI-MS electropherogram for the analysis of three selenium species (SeM, SeC, and SeCM) using 5% acetic acid as electrolyte buffer. The insets give information about the isotopic patterns of the species. (Reprinted from Michalke et al. 1999 Fresenius’ J. Anal. Chem. 363: 456–459.)

342

Analytical Measurements in Aquatic Environments

hyphenated GC technique for volatile organoselenium species. When the inorganic species Se(+IV) and Se(+VI) are to be determined, the preferred method of analysis is IC.242 With this technique, the Se amino acids selenomethionine and selenocysteine can also be determined in the same run. Alternative methods for the analysis of Se amino acids are gas chromatographic analysis with element- or molecule-specific detection after derivatization, for example, with chloroformate reagents243 or in a two-step acylation/esterification reaction.244 Furthermore, CE, coupled to ICP-MS or ESI-MS detection, can be used in the speciation of inorganic selenium species245 and selenium amino acids (Figure 13.19).246

13.4 CONCLUSIONS AND OUTLOOK Methods for the analysis of organic and organometallic compounds are discussed in this chapter. It has become evident that for the analysis of these two classes of compounds, the analyst can draw on a very similar repertoire of analytical techniques with respect to sample preparation, separation, and detection. Chromatographic and, in particular, hyphenated techniques are the workhorses of environmental water analysis. The various formats and technical realizations of mass spectrometers are the most versatile detectors. Their sensitivity and ability to provide structural information at the low and even sub-pg level are an asset and at the same time a prerequisite for (ultra)trace analysis in the aquatic environment. As further significant improvements in detector sensitivity are unlikely, the probable focus of attention in the future will again be on sample preparation. Here, the introduction of new approaches, techniques, and materials for sample preparation can be expected to make a significant impact in this field.

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185. Reemtsma, T. 1996. Methods of analysis of polar aromatic sulfonates from aquatic environments. J. Chromatogr. A 733: 473–489. 186. Eichhorn, P. and T.P. Knepper. 2002. a,b-unsaturated sulfophenylcarboxylates as degradation intermediates of linear alkylbenzenesulfonates: Evidence for omega-oxygenation followed by beta-oxidations by liquid chromatography-mass spectrometry. Environ. Toxicol. Chem. 21: 1–8. 187. Weremiuk, A.M., S. Gerstmann, and H. Frank. 2006. Quantitative determination of perfluorinated surfactants in water by LC-ESI-MS/MS. J. Sep. Sci. 29: 2251–2255. 188. Scott, B.F., C.A. Moody, C. Spencer, et al. 2006. Analysis for perfluorocarboxylic acids/anions in surface waters and precipitation using GC-MS and analysis of PFOA from large-volume samples. Environ. Sci. Technol. 40: 6405–6410. 189. Murphy, R.E. and M.R. Schure. 2008. The analysis of surfactants by multidimensional liquid chromatography. In: S.A. Cohen and M.R. Schure (eds), Multidimensional Liquid Chromatography, pp. 425–446. Hoboken, New York: Wiley. 190. Gonzalez, S., D. Barceló, and M. Petrovic. 2007. Advanced liquid chromatography-mass spectrometry (LC-MS) methods applied to wastewater removal and the fate of surfactants in the environment. Trends Anal. Chem. 26: 116–124. 191. Knepper T.P., D. Barceló, and P. de Voogt (eds). 2003. Analysis and fate of surfactants in the aquatic environment. Comprehensive Analytical Chemistry, Vol. 40. Amsterdam: Elsevier. 192. Kuster, M., M.J. Lopez de Alda, and D. Barceló. 2005. Estrogens and progestogens in wastewater, sludge, sediments, and soil. In: D. Barceló (ed.), Handbook of Environmental Chemistry, Vol. 5, pp. 1–24. Berlin: Springer. 193. Kuster, M., M.J. Lopez de Alda, S. Rodriguez-Mozaz, et al. 2007. Analysis of steroid estrogens in the environment. In: G. Svehla and D. Barceló (eds), Comprehensive Analytical Chemistry, Vol. 50, pp. 219–264. Amsterdam: Elsevier. 194. Petrovic, M., E. Eljarrat, M.J. Lopez de Alda, et al. 2004. Endocrine disrupting compounds and other emerging contaminants in the environment: A survey on new monitoring strategies and occurrence data. Anal. Bioanal. Chem. 378: 549–562. 195. Lopez de Alda, M.J., S. Diaz-Cruz, M. Petrovic, et al. 2003. Liquid chromatography-(tandem) mass spectrometry of selected emerging pollutants (steroid sex hormones, drugs and alkylphenolic surfactants) in the aquatic environment. J. Chromatogr. A 1000: 503–526. 196. Gentili, A., D. Perret, S. Marcheseet, et al. 2002. Analysis of free estrogens and their conjugates in sewage and river waters by solid-phase extraction then liquid chromatography-electrospray-tandem mass spectrometry. Chromatographia 56: 25–32. 197. Petrovic M. and D. Barceló (eds). 2007. Analysis, fate and removal of pharmaceuticals in the water cycle. Comprehensive Analytical Chemistry, Vol. 50. Amsterdam: Elsevier. 198. Öllers, S., H.P. Singer, P. Fässler, et al. 2001. Simultaneous quantification of neutral and acidic pharmaceuticals and pesticides at the low-ng/l level in surface and waste water. J. Chromatogr. A 911: 225–234. 199. Castiglioni, S., R. Bagnati, R. Calamari, et al. 2005. A multiresidue analytical method using solid-phase extraction and high-pressure liquid chromatography tandem mass spectrometry to measure pharmaceuticals of different therapeutic classes in urban wastewaters. J. Chromatogr. A 1092: 206–215. 202. Petrovic, M., M. Gros, and D. Barceló. 2006. Multi-residue analysis of pharmaceuticals in wastewater by ultra-performance liquid chromatography–mass spectrometry. J. Chromatogr. A 1124: 68–81. 201. De˛bska, J., A. Kot-Wasik, and J. Namies´nik. 2004. Fate and analysis of pharmaceutical residues in the aquatic environment. Crit. Rev. Anal. Chem. 34: 51–67. 202. Kot-Wasik, A., J. De˛bska, and J. Namies´nik. 2007. Analytical techniques in studies of the environmental fate of pharmaceuticals and personal-care products. Trends Anal. Chem. 26: 557–568. 203. Daugthon, C.G., T. Jones-Lepp, and D. Washington. 2001. Pharmaceuticals and personal care products in the environment: Scientific and regulatory issues. ACS Symposium Series 791. Washington: American Chemical Society. 204. Peck, A. 2006. Analytical methods for the determination of persistent ingredients of personal care products in environmental matrices. Anal. Bioanal. Chem. 386: 907–939. 205. Ternes A.T., A. Joss, and H. Siegrist. 2004. Scrutinizing pharmaceuticals and personal care products in wastewater treatment. Environ. Sci. Technol. 38: 393A–398A. 206. Matamoros, V., E. Jover, and J.M. Bayona. 2008. Advances in the determination of degradation intermediates of personal care products in environmental matrixes: A review. Anal. Bioanal. Chem. in print (doi:10.1007/s00216-008-2371-7). 207. Champ, M.A. 2000. A review of organotin regulatory strategies, pending actions, related costs and benefits. Sci. Total Environ. 258: 21–71.

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208. Rosenberg, E. 2005. Speciation of tin compounds. In: R. Cornelis, J.A. Caruso, H. Crews, and K.G. Heumann (eds), Handbook of Elemental Speciation, pp. 422–463. Weinheim: Wiley-VCH. 209. Antizar-Ladislao, B. 2008. Environmental levels, toxicity and human exposure to tributyltin (TBT)contaminated marine environment. A review. Environ. Int. 34: 292–308. 210. Abalos, M., J.-M. Bayona, R. Compañó, et al. 1997. Analytical procedures for the determination of organotin compounds in sediment and biota: A critical review. J. Chromatogr. A 788: 1–49. 211. Pellegrino, C., P. Massanisso, and R. Morabito. 2000. Comparison of twelve selected extraction methods for the determination of butyl- and phenyltin compounds in mussel samples. Trends Anal. Chem. 19: 97–106. 212. Donard, O.F.X., S. Rapsomanikis, and J.H. Weber. 1986. Speciation of inorganic tin and alkyltin compounds by atomic absorption spectrometry using electrothermal quartz furnace after hydride generation. Anal. Chem. 58: 772–777. 213. Aguerre, S., G. Lespes, V. Desauziers, et al. 2001. Speciation of organotins in environmental samples by SPME-GC: Comparison of four specific detectors: FPD, PFPD, MIP-AES and ICP-MS, J. Anal. At. Spectrom. 16: 263–269. 214. Compañó, R., M. Granados, C. Leal, et al. 1995. Liquid chromatographic determination of triphenyltin and tributyltin using fluorimetric detection. Anal. Chim. Acta 314: 175–182. 215. Rosenberg, E., V. Kmetov, and M. Grasserbauer. 2000. Investigating the potential of high-performance liquid chromatography with atmospheric pressure chemical ionization-mass spectrometry as an alternative method for the speciation analysis of organotin compounds. Fresenius J. Anal. Chem. 366: 400–407. 216. White, S., T. Catterick, B. Fairman, et al. 1998. Speciation of organotin compounds using liquid chromatography-atmospheric pressure ionisation mass spectrometry and liquid chromatography-inductively coupled plasma mass spectrometry as complementary techniques. J. Chromatogr. A 794: 211–218. 217. Sonak, S., P. Pangam, A. Giriyan, et al. 2009. Implications of the ban on organotins for protection of global coastal and marine ecology. J. Environ. Manage. 90, Suppl. 1: S96–S108. 218. Fent, K. 2006. Worldwide occurrence of organotins from antifouling paints and effects in the aquatic environment. In: I.K. Konstantinou (ed.), Handbook of Environmental Chemistry, Vol. 5, pp. 71–100. Berlin: Springer. 219. Van Cleuvenbergen, R.J.A., D. Chakraborti, and F.C. Adams. 1986. Occurrence of tri- and dialkyllead species in environmental water. Environ. Sci. Technol. 20: 589–593. 220. Radojevic, M. and R.M. Harrison. 1987. Concentrations and pathways of organolead compounds in the environment: A review. Sci. Total Environ. 59: 157–180. 221. Paneli, M., E. Rosenberg, M. Grasserbauer, et al. 1997. Assessment of organolead species in the Austrian Danube-basin using GC-MIP-AED. Fresenius J. Anal. Chem. 357: 756–762. 222. Bergmann, K. and B. Neidhart. 2001. In situ propylation of ionic organotin and organolead species in water samples—extraction and determination of the resulting tetraorganometallic compounds by gas chromatography-atomic absorption spectrometry. J. Sep. Sci. 24: 221–225. 223. Baena, J.R., M. Gallego, M. Valcárcel, et al. 2001. Comparison of three coupled gas chromatographic detectors (MS, MIP-AES, ICP-TOFMS) for organolead speciation analysis. Anal. Chem. 73: 3927–3934. 224. Łobin´ski, R. 1995. Organolead compounds in archives of environmental pollution. Analyst 120: 615–621. 225. Froelich Jr., P.N. and M.O. Andreae. 1981. The marine geochemistry of germanium: Ekasilicon. Science 213: 205–207. 226. Lewis, B.L., M.O. Andreae, P.N. Froelich, et al. 1988. A review of the biogeochemistry of germanium in natural waters. Sci. Total Environ. 73: 107–120. 227. Rosenberg, E. 2008. Germanium: Environmental occurrence, importance and speciation. Rev. Environ. Sci. Bio/Technol. in print (doi:10.1007/s11157-008-9143-x). 228. Hambrick III, G.A., P.N. Froelich Jr., M.O. Andreae, et al. 1984. Determination of methylgermanium species in natural waters by graphite furnace atomic absorption spectrometry with hydride generation. Anal. Chem. 56: 421–424. 229. Jiang, G.B. and F.C. Adams. 1997. Direct determination of trimethylgermanium in water by on-column capillary gas chromatography with flame photometric detection using quartz surface-induced germanium emission. J. Chromatogr. A 759: 119–125. 230. Jiang, G.B. and F.C. Adams. 1997. Evaluation of gas chromatography with a flame photometric detector based on quartz surface-induced emission for determining the speciation of inorganic and methylgermanium compounds. Anal. Chim. Acta 337: 83–91.

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231. Lewis, B.L., M.O. Andreae, and P.N. Froelich. 1989. Sources and sinks of methylgermanium in natural waters. Marter. Chem. 27: 179–200. 232. Jiang, G. B., M. Ceulemans, and F.C. Adams. 1996. Optimization study for the speciation analysis of organotin and organogermanium compounds by on-column capillary gas chromatography with flame photometric detection using quartz surface-induced luminescence. J. Chromatogr. A 727: 119–129. 233. Tanzer, D. and K.G. Heumann. 1990. GC determination of dimethyl selenide and trimethyl selenonium ions in aquatic systems using element specific detection. Atmos. Environ. 24: 3099–3102. 234. Pyrzynska, K. 2002. Determination of selenium species in environmental samples. Microchim. Acta 140: 55–62. 235. de la Calle Guntiñas, M.B., M. Ceulemans, C. Witte, et al. 1995. Evaluation of a purge-and-trap injection system for capillary gas chromatography-microwave induced plasma-atomic emission spectrometry for the determination of volatile selenium compounds in water. Mikrochim. Acta 120: 73–82. 236. de la Calle Guntiñas, M.B., R. Łobin´ski, and F.C. Adams. 1995. Interference-free determination of selenium(IV) by capillary gas chromatography-microwave-induced plasma atomic emission spectrometry after volatilization with sodium tetraethylborate. J. Anal. At. Spectr. 10: 111–115. 237. Gómez-Ariza, J.L., J.A. Pozas, I. Giráldez et al. 1999. Use of solid phase extraction for speciation of selenium compounds in aqueous environmental samples. Analyst 124: 75–78. 238. Pérez-Sirvent, C. and M.-J. Martínez-Sánchez. 2007. Comparison of two derivatizing agents for the simultaneous determination of selenite and organoselenium species by gas chromatography and atomic emission detection after preconcentration using solid-phase microextraction. J. Chromatogr. A 1165: 191–199. 239. Brunori, C., M.B. de la Calle-Guntiñas, R. Morabito. 1998. Optimization of the reduction of Se(VI) to Se(IV) in a microwave oven. Fresenius J. Anal. Chem. 360: 26–30. 240. Uden, P.C. 2002. Modern trends in the speciation of selenium by hyphenated techniques. Anal. Bioanal. Chem. 373: 422–431. 241. Dietz, C., J. S. Landaluze, P. Ximenez-Embun. 2004. SPME-multicapillary GC coupled to different detection systems and applied to volatile organo-selenium speciation in yeast. J. Anal. At. Spectrom. 19: 260–266. 242. Afton, S., K. Kubachka, B. Catron, et al. 2008. Simultaneous characterization of selenium and arsenic analytes via ion-pairing reversed phase chromatography with inductively coupled plasma and electrospray ionization ion trap mass spectrometry for detection. Applications to river water, plant extract and urine matrices. J. Chromatogr. A 1208: 156–163. 243. Haberhauer-Troyer, C., G. Álvarez-Llamas, E. Zitting, et al. 2003. Comparison of different chloroformates for the derivatisation of seleno amino acids for gas chromatographic analysis. J. Chromatogr. A 1015: 1–10. 244. Peláez, M.V., M.M. Bayón, J.I.G. Alonso, et al. 2000. Comparison of different derivatization approaches for the determination of selenomethionine by GC-ICP-MS. J. Anal. At. Spectrom. 15: 1217–1222. 245. Michalke, B. and P. Schramel. 1998. Selenium speciation by interfacing capillary electrophoresis with inductively coupled plasma-mass spectrometry. Electrophoresis 19: 270–275. 246. Michalke, B., O. Schramel, and A. Kettrup. 1999. Capillary electrophoresis coupled to inductively coupled plasma mass spectrometry (CE/ICP-MS) and to electrospray ionization mass spectrometry (CE/ ESI-MS): An approach for maximum species information in speciation of selenium. Fresenius J. Anal. Chem. 363: 456–459.

14

Introducing the Concept of Sustainable Development into Analytical Practice: Green Analytical Chemistry Waldemar Wardencki and Jacek Namies´nik

CONTENTS 14.1 14.2 14.3 14.4 14.5

Introduction ...................................................................................................................... History of Green Analytical Chemistry ........................................................................... Implementation of Greener Analytical Chemistry Approaches in Laboratory Practice ..... General Characteristics of the Analytical Process ........................................................... Greening Analytical Chemistry in Sample Pretreatment: General Characteristics ......... 14.5.1 Accelerated Solvent Extraction .......................................................................... 14.5.2 Ultrasonic and Microwave Extraction ............................................................... 14.5.3 Solid-Phase Microextraction .............................................................................. 14.5.4 Stir Bar Sorptive Extraction ............................................................................... 14.5.5 Thin-Film Microextraction ................................................................................ 14.5.6 Single-Drop Microextraction ............................................................................. 14.5.7 Liquid-Phase Microextraction ........................................................................... 14.5.8 Pressurized Hot Water Extraction ..................................................................... 14.5.9 Supercritical Fluid Extraction ............................................................................ 14.5.10 Alternative Solvents: The Application of ILs .................................................... 14.6 Greener Separation Techniques ........................................................................................ 14.7 Advances in Electrochemistry Sensing Technology Relevant to Green Analytical Chemistry ............................................................................................. 14.8 Miniaturization in Analytical Chemistry Methods .......................................................... 14.9 Conclusions ....................................................................................................................... References ..................................................................................................................................

353 354 355 356 356 356 357 357 358 358 359 359 360 360 361 361 362 362 363 364

14.1 INTRODUCTION Since the Rio de Janeiro conference in 1992 the issue of sustainable development has become a matter of increasing global concern. The main goals of sustainable development are focused on sound economic development in accordance with an intact environment and a fair global social balance. The trend of sustainable development requires chemistry to be cleaner and greener. The beginning of green chemistry is frequently considered to be a response to the need to reduce the damage to the environment caused by man-made materials and the processes for producing them. 353

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The term “green chemistry” was first used in 1991 by P.T. Anastas in a special program launched by the US Environmental Protection Agency (EPA) to encourage industry, academia, and governments to introduce sustainable development to chemistry and chemical technology. In 1995, the annual US Presidential Green Chemistry Challenge was announced. Shortly afterwards, similar awards were established in European countries. In 1996, the Working Party on Green Chemistry came into existence within the framework of the International Union of Applied and Pure Chemistry (IUPAC). One year later, the Green Chemistry Institute (GCI) was formed with chapters in 20 countries to facilitate contacts between governmental agencies and industrial corporations on the one hand, and universities and research institutes on the other with regard to the design and implementation of new technologies. Green chemistry—otherwise referred to as environmentally benign chemistry, clean chemistry, the atom economy, and benign-by-design chemistry—brings a fresh approach to the synthesis, processing, and application of chemical substances, the idea being to reduce the threats to health and the environment. It is usually presented as a set of 12 principles put forward by Anastas and Warner1 embodying instructions on how to implement new chemical compounds, syntheses, and technological processes; the rules for introducing green chemical synthesis on a technological scale were set out by Winterton.2 The significance of green chemistry was highlighted in a cover story in Chemical Engineering News.3 The fi rst books and journals on the subject of green chemistry were published in the 1990s, including Journal of Clean Processes and Products (Springer-Verlag) and Green Chemistry, sponsored by the Royal Society of Chemistry. Some journals, such as Environmental Science and Technology and Journal of Chemical Education, have regular dedicated sections on green chemistry, whereas others devote complete issues to this new approach.4,5 All these publications reflect the importance attached to the different aspects of green chemistry in current research activities. The first conference highlighting green chemistry was held in Washington in 1997, since when other, similar conferences have been held on a regular basis in order to raise the awareness of and participation in this greener vision.6

14.2

HISTORY OF GREEN ANALYTICAL CHEMISTRY

The 12 principles of green chemistry proposed by Anastas and Warner1 address mainly aspects of synthetic chemistry; the idea of green analytical chemistry was conceived only later.7,8 At first, it did not catch on, but as the “green chemistry movement” has gained in momentum, the green approach to analytical chemistry has become a key part of green chemistry. Analytical chemists have long been environmentally sensitive, but the word “green” has rarely been used in descriptions of their activities in the last 15 years. Since the year 2000, however, there has been a dramatic increase in the number of papers dealing with green or clean analytical chemistry. A few interesting reviews have been published recently, some addressing general issues of green analytical chemistry,9⫺11 and others particular methodologies.12⫺14 The irony is that the methods used in laboratories to analyze the state of environmental pollution, as well as the analytical chemists applying them, through the uncontrolled disposal of reagents, solvents, and other chemical wastes, may themselves be the source of large amounts of pollutants entering the environment. Traditional analytical procedures require considerable quantities of chemical compounds; sampling, and especially the preparation of samples for their final determination, frequently involves the formation of large amounts of pollutants (vapors, liquid effluents— waste reagents and solvents, and solid waste). If environmental pollution by analytical reagents and so on is to be avoided, the rules of green chemistry must be introduced into chemical laboratories on a large scale. Analytical chemists strive for the traditional goals of accuracy, precision, sensitivity, and low detection limits; but by implementing green chemistry rules in laboratory practice, they are demonstrating their awareness of the impact of their work on the environment.

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Based on a survey of the recent analytical literature, this chapter reviews a number of innovatory methodologies for sample preparation, as well as the development and application of new approaches to traditional analytical methods in order to make this field of chemistry greener.

14.3

IMPLEMENTATION OF GREENER ANALYTICAL CHEMISTRY APPROACHES IN LABORATORY PRACTICE

Analytical chemistry is still a relatively poorly examined area of green chemistry. The main objective of green analytical chemistry is to apply analytical procedures and devices that generate less hazardous waste, are safer to use, and kinder to the environment. This objective can be achieved through the development of entirely new analytical methodologies or the modification of old ones to incorporate procedures using either fewer hazardous chemicals or at least smaller quantities of them. The general strategy toward making analytical methodologies greener involves not only changing or modifying reagents and solvents, or reducing the amounts of chemicals used, but also the miniaturization and even the elimination of sampling by measuring the analytes of interest in situ in real time and on-line. In accordance with the 12 principles of green chemistry, the actions to be taken to achieve a greener analytical chemistry are easily stated. The following are priority issues with regard to analytical procedures: • • • •

Eliminating or minimizing the use of chemical reagents, particularly organic solvents. Eliminating chemicals with a high toxicity and ecotoxicity. Reducing labor- and energy-intensive steps (per analyte). Reducing the impact of chemicals on human health.

X-ray fluorescence,15,16 surface acoustic waves (SAW) for determining volatile organic compounds (VOCs),17,18 and immunoassays19⫺21 are examples of direct analytical techniques (in which a sample preparation step is unnecessary) that are environmentally friendly. In addition, there are environmentally benign procedures from which reagents and solvents have been eliminated or their quantities minimized (calculated per analytical cycle): • • • • • • • • • • •

Solid-phase extraction (SPE)22,23 Accelerated solvent extraction (ASE)24 Solid-phase microextraction (SPME)25 Stir bar sorptive extraction (SBSE)26 Thin-film microextraction27 Single-drop microextraction (SDME)28 Liquid-phase microextraction (LPME)29 Supercritical fluid extraction (SFE)30,31 Extraction in automated Soxhlet apparatus32 Vacuum distillation of VOCs33 Mass spectrometry with membrane interface (MIMS).34

The next important challenge of green analytical chemistry is in-process monitoring. Developing and using in-line or on-line analyzers enable analytes to be determined in real time, and disturbances to be detected already in the initial steps of a process. This means of analysis provides rapid information and the opportunity for preventive measures to be taken—the process can be stopped or its operational parameters altered—with an overall improvement in efficiency. The following sections discuss recent advances in green analytical chemistry in the context of the whole analytical process, that is, from sample collection, sample preparation, to sample analysis, as well as the characteristics of some traditional methodologies that have always been environmentally benign but were never described as “green.”

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14.4 GENERAL CHARACTERISTICS OF THE ANALYTICAL PROCESS Analytical chemistry is important in that it supports the development of chemical engineering and technology for the production of chemicals and confirms (or not) the environmental friendliness of new methods, processes, and products. Analytical procedures deliver information about chemical substances, their occurrence in the environment and in organisms. Analytical chemistry also affects sociopolitical decisions: The results of chemical analysis provide strong arguments for enacting new laws and administrative regulations with regard to food quality, the freshness of raw materials, and the nutritive values of processed food. Accurate assessments of these parameters, as well as the determination of food additives and contaminants, are especially important to reassure consumers that the products they purchase are safe. In order to provide the relevant data, analysts have to develop better, less labor-intensive, faster, and more accurate procedures. The analytical process consists of a series of steps: sampling, sample handling, laboratory sample preparation, separation and quantitation, and statistical evaluation. Each one of these steps is important if accurate results are to be obtained, but the key component of the analytical process is sample preparation. It is important to bear in mind that these analytical steps are consecutive: the next step cannot begin until the preceding one has been completed. If any one of these steps is not carried out properly, the overall performance of the procedure will be poor, errors will be introduced, and inconsistency in the results can be expected. The application of green chemistry rules in the design of new analytical methods is the key to diminishing the adverse effects of analytical chemistry on the environment. The same ingenuity and innovation that were applied earlier to obtain excellent sensitivity, precision, and accuracy are now invoked to reduce or eliminate the application of hazardous substances in analysis. Analytical chemistry is generally considered a small-scale activity; but in view of the very large numbers of runs performed in controlling and monitoring laboratories, the scale becomes comparable with that of the fine chemicals or pharmaceutical industries.

14.5

GREENING ANALYTICAL CHEMISTRY IN SAMPLE PRETREATMENT: GENERAL CHARACTERISTICS

The choice of sample preparation method is crucial in chemical analysis because it is often the most critical and time-consuming step of an analytical process.35 There is a wide choice of methods for sample pretreatment and preparation for further analysis. Unfortunately, however, there are no universal methods of sample treatment because analytical samples come in a huge variety of forms. Ideally, the sample preparation methodology should be solvent-free, simple, inexpensive, efficient, selective, and compatible with final analytical methods. There is an urgent need to evaluate the analytical procedures in current use, not only with respect to the reagents, instrumental costs, and analytical parameters, but also in the context of their adverse effect on the environment. The continual development of new solventless sample preparation methods is a good example of activities in this field. Indeed, recent years have witnessed particularly rapid progress in the development of these techniques,36,37 which provide higher yields, better sample cleanup, cost effectiveness and chemist safety, and are also less harmful to the environment. Some examples of modern analytical techniques used for sample pretreatment are now presented.

14.5.1 ACCELERATED SOLVENT EXTRACTION ASE—also referred to as pressurized fluid extraction (PFE)—offers an order of magnitude of additional reductions in solvent use with faster sample processing time, and with the potential of automated, unattended extraction of multiple samples. Briefly, with ASE a solid sample is enclosed in a cell containing an extraction solvent; after the cell has been sealed, the sample is permeated by

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the extracting solvent under elevated temperatures and pressure for short periods (5–10 min). Typically, the samples are extracted under static conditions, where the fluid is held in the cell for controlled time periods to allow sufficient contact between the solvent and the solid for efficient extraction. Alternatively, dynamic or flow-through techniques can be used. Compressed gas is used to purge a sample extract from the cell into a collection vessel. ASE achieves rapid extraction with small volumes of conventional organic solvents by using high temperatures (up to 200°C) and high pressures (up to 20 MPa) to maintain the solvent in a liquid state. The use of liquid solvents at elevated temperatures and pressures improves efficiency compared with extractions at or near room temperature and atmospheric pressure because of enhanced solubility and mass-transfer effects and the disruption of surface equilibrium. A number of review papers with very detailed descriptions and evaluations of this sample pretreatment technique have been published.38,39 ASE has been used to extract hydrophobic organic compounds from different environmental samples.40⫺42 Some studies have compared ASE with conventional techniques such as SFE and Soxhlet extraction: the performance of ASE was consistently equivalent to or better than conventional techniques such as Soxhlet and sonication extraction.

14.5.2 ULTRASONIC AND MICROWAVE EXTRACTION Ultrasonic and microwave extractions are relatively simple and inexpensive techniques for greening extractions. Ultrasonic extraction uses high-frequency acoustic waves to create microscopic bubbles in liquids. When these bubbles burst, small shock waves and cavitations occur that are particularly well suited for breaking up solids and promoting their dissolution. This technique has been used to extract a variety of organic compounds, for example, nicotine from pharmaceutical samples into heptane for gas chromatography (GC) analysis (reducing the amount of solvent required by 5/6 compared to the conventional method),43 and phthalates from cosmetics into ethanol/water for highperformance liquid chromatography (HPLC),44 and also inorganic analytes, such as mercury from milk samples.45 Microwave-assisted extractions (MAE) can be performed in open (focused MAE) or closed (pressurized MAE) flasks. This technique is commonly used for extractions from complex and difficult sample matrices, replacing time- and solvent-intensive Soxhlet extractions or hydrodistillations.46 MAE is also widely applied to environmental samples, for example, for extracting polycyclic aromatic hydrocarbons (PAH) from soil, methylmercury from sediments, and trace metals and pesticide residues from plant material.47,48 The use of microwave treatment instead of hydrodistillation offers a solvent-free separation technique: essential oils are heated and dry-distilled.46

14.5.3 SOLID-PHASE MICROEXTRACTION SPME is a fast, universal, sensitive, solventless, and economical method of preparing samples for GC or HPLC analysis, enabling detection limits at a level of 5–50 ppt for volatile, semivolatile, and nonvolatile compounds to be achieved. The approximate sample preparation time is usually 2–15 min.49,50 The effectiveness of analyte preconcentration using SPME depends on a number of parameters, for example, the type of fiber, sample stirring, extraction time, and ionic strength. The sensitivity of the technique depends mainly on the value of the partition coefficient of the analytes partitioned between the sample and the fiber stationary phase. The efficiency of preconcentration depends on both the type of fiber used and its thickness (amount). This type of fiber affects the amount and character of the sorbed species.51 The general rule “like dissolves like” applies here, that is, polar compounds are sorbed on polar fibers, and nonpolar compounds on nonpolar fibers. A broad range of standard fibers is commercially available.

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A great number of compounds can be determined using this technique: it enables the isolation of pesticides from different matrices52⫺54 and of solvent residues,55 and also the analysis of complex mixtures such as aroma compounds.56⫺58 An SPME fiber can be exposed in two modes—by immersing it directly in the liquid sample to be analyzed (direct immersion SPME—DI-SPME), or by exposing it to the headspace (HS-SPME). In the latter case, the fiber is inserted into the headspace, above a liquid or solid sample. Sampling volatile analytes from samples having complex matrices usually takes place in the HS-SPME mode. This variant yields decidedly better results in the determination of aroma compounds59 and other volatile components.60 Moreover, HS-SPME prolongs the life of the fiber because it is not in direct contact with the sample. On the other hand, the direct extraction of less volatile compounds from solution is possible using DI-SPME. But in this case, the fiber deteriorates more quickly, increasing the cost of analysis. Headspace sampling is therefore employed whenever possible. 100 ␮m polydimethylsiloxane (PDMS)61 and divinylbenzene-PDMS (DVB-PDMS)62 are undoubtedly the most frequently and most universally used fiber materials. The preferred final method of analyzing enriched compounds is GC coupled with mass spectrometry (MS) (GC-MS),63 although HPLC is sometimes used as an alternative.64 Another important mode of operation in SPME is in-tube SPME.65 In this system, usually coupled on-line to HPLC, a finite portion of sample is drawn through an internally coated capillary tube and then ejected into the sample vial. This technique requires more complex instrumentation than that used for standard SPME, but a greater sensitivity is obtainable with a longer tube (and consequently more sorbent). Two solvent desorption modes—are usually applied for introducing species into HPLC: off-line desorption and on-line desorption. In the latter, the HPLC mobile phase is used for desorbing the analytes.

14.5.4 STIR BAR SORPTIVE EXTRACTION In 1999, a new technique of sorptive extraction called SBSE was introduced into analytical practice.66 Developed to extract organic analytes from liquid samples, it is based on the sorption of analytes onto a thick film of PDMS coated on an iron stir bar.67,68 Originally, the stir bars were prepared by removing the Teflon® coating from existing stir bars, reducing the outer diameter of the magnet, and enclosing the magnet in a glass tube to give a 1.2 mm outer diameter. Silicone tubing with an internal diameter of 1.5 mm and an outer diameter of 3 mm was then slid over the magnetic glass tube. However, as the stir plate is itself magnetic, the use of a magnetic stir bar is not required. Nonmagnetic stir bars were prepared from stainless steel rods with an outer diameter of 0.8 mm and a length of 40 mm. The total amounts of PDMS material present on the 10 and 40 mm stir bars were 75.7 and 300.9 mg, respectively, which convert with a density of 0.825 g mL⫺1 to volumes of 92 and 365 mL; as the PDMS tubing contains approximately 40% (v/v) of fumed silica as filling material, as determined with solid-state nuclear magnetic resonance (NMR) and thermogravimetric analysis (TGA), the effective volumes of PDMS are 55 and 219 mL, respectively. The stir bar is placed in an aqueous sample and extraction takes place during stirring. Because of the low phase ratio (the volume of the water phase divided by the volume of the PDMS phase), very high recoveries were obtained, especially for volatile compounds. The efficiency of SBSE has been compared with other sorptive techniques.69 This technique has been applied to the extraction of different types of organic compounds in aqueous solutions,70,71 wine,72 and in fruits and vegetables.73,74 In combination with thermodesorption-GC-MS,75 SBSE enables low detection limits to be achieved. As an alternative, the analytes from the stir bar can be desorbed by liquid extraction and the extract injected into a liquid chromatography (LC) system.76

14.5.5

THIN-FILM MICROEXTRACTION

To obtain a greater volume of the extraction phase, the surface area of the polymer is extended, which has been done by using membranes instead of fiber coatings. The use of a thin membrane has the advantage that enhanced extraction efficiency and hence high sensitivity can be achieved

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without the disadvantage of longer equilibrium times, as is the case when thick phase coated stir bars are used. A cross-linked commercial PDMS membrane27 was successfully evaluated for the extraction of PAH in headspace mode. An in-house prepared membrane of PDMS77 was applied to both nonpolar PAH extraction and to polar phenolic compounds. A commercial porous polysulfone hollow fiber membrane, coated with a variety of hydroxylated polymethacrylate compounds,78 tended to swell when used in water. This is an advantage over classical SPME for the extraction of alkylsubstituted phenols in seawater samples. One of the drawbacks of the system, however, is the necessity for a thermal desorption system or a high-volume GC injector.

14.5.6 SINGLE-DROP MICROEXTRACTION In 1997, Jeannot and Cantwell79 as well as He and Lee80 independently introduced a simple kind of microextraction in which an organic drop hangs from the tip of a GC syringe needle. SDME is a simple method of reducing solvent consumption; indeed, the small amounts of solvent used in SDME are an advantage of this technique. Pure solvents or mixtures can be used for the selective extraction of different organic species.81 This technique therefore represents an inexpensive and attractive alternative to SPME requiring a standard GC syringe only. SPME does not give a solvent peak in GC, but analyte desorption from the polymer in a hot injector is significantly slower than solvent evaporation, resulting in peaks with a tendency to tail. Alternatively, stirring the sample increases extraction efficiency by SPME, but stirring or sonification of samples in SDME experiments can cause the organic drop to fall off the needle. Consequently, these two methods cannot be applied together with SDME. Nevertheless, the adequate precision, linearity, and repeatability of SDME indicate that this virtually solventless extraction method is reliable for routine analysis. A review of SDME including 27 references28 summarizes investigations in this rapidly growing field up till 2002. In a more recent work, a benzyl alcohol microdrop was found to be the optimum solvent for extracting solvent residuals from vegetable oils.82 Octanol provided optimum extraction efficiency for a variety of short-chain alcohols83 from water samples. The field of applications has even been extended to the determination of organometallic compounds such as tributyltin,84 which was extracted into a decane microdrop. Using hexane as a solvent, volatile halohydrocarbons could be extracted in this way from aqueous samples,85 with limit of detection (LOD) as low as 0.001 ␮g L⫺1 for CCl4 using GC with electron-capture detection. An ionic liquid (IL) (l-octyl-3methylimidazolium hexafluorophosphate) as extraction solvent was found to be suitable for the extraction of substituted phenols86 and formaldehyde from mushrooms87 following derivatization with 2,4-dinitrophenylhydrazine. Even though this is a virtually solventless, inexpensive, fast, and simple method for analyte extraction and/or preconcentration, frequent problems with drop stability and lack of sensitivity have been reported. In an attempt to overcome these limitations, a microlitersize liquid membrane was placed between the sample (octane) and the microdrop (water); simultaneous extraction/back extraction was found to be taking place.88

14.5.7 LIQUID-PHASE MICROEXTRACTION This technique can be considered as a further development of SDME. To give one example: the organic phase was contained within the lumen of the fiber and the sample solution was filled into a vial with a screw top/silicone septum. Two conventional medical syringe needles (guiding needles) were inserted through the silicon septum in the screw top and the two ends connected to each other by a piece of Q3/2 Accurel KM polypropylene hollow fiber. The latter served to contain the microliter volume of extracting solution. For extraction in combination with GC the hollow fiber was filled with n-octanol. For extraction in combination with capillary electrophoresis (CE) or HPLC the hollow fiber mounted on the guiding needles was first dipped into n-octanol for 5 s to immobilize the solvent in pores. Then, the fiber was placed in the sample and the extraction was performed. After extraction, the acceptor solution was collected in microvials by the application of a small head pressure on one of the guiding steel needles for automated analysis by GC or CE.

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The disposable nature of the hollow fiber eliminates the possibility of carry-over effects and cross-contamination, thus providing enhanced reproducibility. Further, the small pore size prevents large molecules and particles present in the donor solution from entering the acceptor phase, providing effective matrix/analyte separation. Psillakis and Kalogerakis89 reviewed the hollow fiber configurations, LPME sampling modes, and different parameters to be taken into account during method optimization, while another review focused on the use of LPME for drug analysis.90 Rasmussen and Pedersen-Bjergaard91 examined the basic extraction principles, technical setup, recovery, enrichment, extraction speed, selectivity, and applications. A disadvantage of LPME is the lack of precision, which may be because the whole operation, from fiber preparation and conditioning to the handling of the extract, is done manually.

14.5.8 PRESSURIZED HOT WATER EXTRACTION Techniques that reduce solvent consumption during sample preparation have also become more commonly applied, for example, pressurized hot water extraction (PHWE), which has replaced conventional organic solvents in a variety of extraction processes.92,93 Because PHWE employs water, it can also be classified as a “solventless” technique. Selective extraction can be achieved by temperature tuning. Temperatures below the critical value of water but usually above 100°C are usually employed. When working with a liquid phase, the pressure must be sufficient to prevent the water from vaporizing. In the vapor phase some pressure is generally needed for the effective transportation of water. A high temperature increases the initial desorption of the compounds from the sample particles. In addition, rapid diffusion, low viscosity, and low surface tension are achieved at higher temperatures. On the other hand, thermally labile compounds may decompose, and the quantities of coextracted compounds may be greater than at lower temperatures.

14.5.9 SUPERCRITICAL FLUID EXTRACTION The superior solvation qualities of supercritical fluids over conventional liquids have been known for more than a century, since 1879 in fact, when Hannay and Hogarth investigated the solubility of different inorganic salts in supercritical ethanol. But it was not until the late 1960s that the extraction potential of supercritical fluids was recognized. Several liquids and gases can be brought into the supercritical phase. Different solvents can be selected as extraction media for use in analytical-scale SFE. Carbon dioxide is most commonly used as an SFE medium because of its desirable properties and easy handling; it is relatively inexpensive and commercially available at a purity grade acceptable for most analytical applications. Another advantage of carbon dioxide is that the polarity can easily be adjusted by adding modifiers such as methanol to the supercritical fluid or the extraction vessel. SFE is superior to traditional extraction and cleanup for organic compounds in samples in every respect: Solvent use is reduced to a minimum, analysis time is reduced to 2–3 h, a large sample throughput is possible by using automated systems, repeatability is better than with traditional techniques, and optimization for different compound classes is possible, not to mention simultaneous analyses of many different organic compounds in one sample. The considerable reduction in analysis time and cost opens up the possibility of performing large monitoring studies covering many different compounds. There are review articles94,95 examining the different aspects of the introduction of SFE into analytical practice. Studies of new approaches to SFE and of fresh applications of this efficient extraction technique are on-going. The following aspects have been accorded special attention: • Restrictor plugging in off-line SFE.96 • A new analyte collection method for off-line SFE based on mixing an expanding supercritical effluent with overheated organic solvent vapor.97

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• The collection capacity of a solid-phase trap in SFE.98 • The design of an SFE-GC system with quantitative transfer of extraction effluent to a megabore capillary column.99 • The application of SFE to physicochemical studies (e.g., the determination of partition coefficients).100

14.5.10

ALTERNATIVE SOLVENTS: THE APPLICATION OF ILS

The properties of ILs (ILs are composed of ions with a melting point close to or below room temperature) are very promising for green chemistry applications; they are nonvolatile and good solvents for many organic and inorganic materials. They behave very differently from conventional molecular liquids, and one of their advantages is their thermal robustness, which offers a broad thermal operation range (typically from ⫺40°C to 200°C). ILs can be applied not only to existing methods whose sensitivity and selectivity of analysis should be improved, but their behavior and properties offer new opportunities in chemical analysis. Their main advantage over organic solvents for applications in analytical chemistry is their low volatility coupled with high thermal stability up to 260°C, which make them useful as solvents for working at high temperatures, and also as stationary phases in GC.101,102 They provide symmetrical peak shapes, and because their ranges of solvation-type interaction are different for anions and cations, they exhibit a dual selectivity behavior. The low volatility of ILs makes them useful as solvents working under high vacuum, and together with their more amorphous solid analogs they are convenient in matrix-assisted laser-desorption/ ionization-mass spectroscopy (MALDI-MS) analysis.103,104 ILs have good solvating properties which, together with their excellent spectral transparency, make them suitable solvents for spectroscopic measurements of a wide range of organic and inorganic species.105 Reliable solution spectra have been reported for highly charged complex ions with high- and low-oxidation states in the UV, visible, and IR regions. They are also superior to the standard solvents used as separation media in liquid–liquid extraction in that high separation efficiencies and selectivities are achievable, for example, for the extraction of sulfur and nitrogen compounds from gasoline and diesel oil.106 With the use of ILs as an electrolyte medium, it is possible to achieve a wider range of operational temperatures and conditions relative to the more conventional electrolytic media. They are, moreover, promising materials in a variety of electrochemical devices such as batteries, fuel cells, sensors, and electrolytic windows.107

14.6 GREENER SEPARATION TECHNIQUES The main requirements for analysts using chromatographic methods wishing to implement the principles of green analytical chemistry are as follows108: • Utilizing direct chromatographic analysis whenever possible, as it permits analytes in a sample to be determined without the need for pretreatment or sample preparation • Reducing labor and energy demands, for example, reducing sample preparation time when direct chromatographic analysis is not possible • Eliminating or reducing the amount of solvent from sample preparation steps applied before final chromatographic analysis • Conducting all operations with solvents in hermetic systems • Reducing matrix interferences • Shortening chromatographic run times • Integrating the steps of analytical procedures, for example, by using hyphenated techniques

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The principles of green chemistry can be implemented in GC in many ways. First and foremost, eliminating or minimizing the amount of solvent in sample preparation techniques prior to final chromatographic analysis is strongly recommended. Therefore, techniques using gas and supercritical fluids for the extraction of numerous pollutants are very common. Rapid chromatography, especially with field-portable instrumentation, has gained in importance,109 as has the coupling of GC to techniques with a high identification potential, for example, to MS (GC-MS), because confirmation can be achieved in the same step as analysis with a second dimension of information. This provides increased confidence in the result in conjunction with increased effectiveness. The principles of green analytical chemistry have also been implemented in electrically driven separation methods in that solvent and sample consumption have been reduced, selectivity increased, analysis times shortened, and mechanically simpler instruments designed.

14.7 ADVANCES IN ELECTROCHEMISTRY SENSING TECHNOLOGY RELEVANT TO GREEN ANALYTICAL CHEMISTRY The advantages of electrochemical systems include high sensitivity and selectivity, a wide linear range, as well as minimal space, power requirements, and instrumentation. Stricter environmental control and effective process monitoring have created considerable demands for innovative analytical methodologies. For meeting the requirements of green analytical chemistry, new devices and procedures with negligible waste generation or no hazardous substances, and in situ real-time monitoring capability, are needed. The combination of modern electrochemical techniques with the breakthrough in microelectronics and miniaturization has enabled the introduction of powerful analytical devices for effective process or pollution control. The performance of electrochemical measurements depends intimately on the material of the working electrode. For many years, the mercury working electrode was frequently used owing to its attractive behavior and its highly reproducible, renewable, and smooth surface; at the same time, it posed a toxicity hazard. New developments in the electrode field have dramatically improved the greenness of electrochemistry. Various nonmercury electrodes have been suggested, such as bismuthfilm electrodes and new ion-selective electrodes.110,111 These provide better-quality trace-metal measurements than those achievable with mercury electrodes. In addition, bismuth is a green element—it has a low toxicity and for this reason it is widely used in the pharmaceutical industry. Also, carbon (and other solid)-based electrodes have shown themselves to be readily adaptable as electrochemical biosensors, for example, for the determination of glucose, nitrate, and polyphenol. Another way of implementing the rules of green chemistry is the miniaturization of solid electrodes; this offers many practical advantages, including a reduction in sample consumption. Furthermore, the significant decrease in resistance makes for easier voltammetric measurements in low-ionic-strength water samples.112

14.8 MINIATURIZATION IN ANALYTICAL CHEMISTRY METHODS Miniaturization, one of basic trends in analytical chemistry, is playing a very important part in “greening” analytical methodologies.113⫺116 The main objectives of miniaturization are to • • • • • •

Improve existing methodologies Address new analytical problems Provide support for automation and simplification Reduce solvent and reagent consumption (hazard minimization) Reduce energy consumption Reduce the dimensions of analytical devices

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Initially, the main goal of miniaturization was to enhance the analytical performance of devices rather than to reduce their size. However, it was found that such tools had the advantage of reducing the consumption of sample and reagents, for example, the smaller consumption of carrier and mobile phases in separation systems (the first analytical system to be miniaturized was the gas chromatograph). Research in this area focused on the development of components such as micropumps, microvalves, and chemical sensors. In the last 10 years considerable interest has been shown in the production of microfluidic analytical devices that integrate multiple sample-handling processes with the actual measurement step on a microchip platform. Such devices are referred to as “micro total analysis systems” (␮TAS), also called “labs-on-a-chip.”114 The whole analytical procedure, including sample pretreatment, derivatization, and separation, is carried out on a single platform. The high degree of integration of the analytical procedure implies that the principles of green chemistry can be applied to all steps of the analytical process. Microminiaturization is an especially important approach for minimizing the waste generated and is essential for analysis when the amount of sample available is extremely small, usually at a scale of less than microliters. The amount of waste generated can be reduced by 4–5 orders of magnitude in comparison to conventional liquid chromatographic analysis (e.g., 10 ␮L per day as against 1 L per day). Such a considerable reduction in waste generation and material usage has enormous implications for green chemistry. Additionally, the downscaling and integration of the analytical process make such microsystems particularly attractive as green chemistry analytical tools, especially for on-site environmental or industrial applications.

14.9 CONCLUSIONS Growing public concern over protecting our environment is obliging all chemists to modify their chemical activities in such a way that they will be conducted in an environmentally friendly manner. This can be realized within the framework of the principles of green chemistry. Green chemistry is not a new branch of science, and emphasizing its importance is not a political slogan. It is a new philosophical approach which, through the dissemination and application of green chemistry principles, can contribute to sustainable development. New analytical methodologies are being developed for implementation according to green chemistry standards, and they will be useful in evaluating the effects of chemical processes on the environment. The application of green chemistry rules to the design of analytical methods is a key factor in efforts to diminish the negative effect of analytical chemistry on the environment. The same ingenuity and innovation applied earlier to obtain excellent sensitivity, precision, and accuracy is now being used to reduce or eliminate the application of hazardous substances in analysis. Great interest is being shown in solventless techniques of sample preparation. This is for both ecotoxicological and economic reasons: the emission of toxic solvents into the environment is avoided, as can the high costs of recycling expensive, high-purity solvents, for example, by distillation. Furthermore, most of these techniques can be automated and quite easily coupled to “green” final methods of analysis, for example, GC. Efforts are still being undertaken to shorten sample preparation time so that a given preparation method can be linked up with high-speed chromatography. An important aspect of green chemistry research is the development of new analytical methodologies, for example, the design of new analytical tools for real-time industrial process monitoring and for preventing the formation of toxic materials. Similarly, a real-time field measurement capability is being developed to replace the traditional method of sample collection and transport to a laboratory. This can be done by developing and using in-line or on-line analyzers, which allows analytes to be determined in real time and disturbances to be detected already in the initial steps of a process. Such a mean of analysis supplies rapid information and enables effective preventive

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measures to be taken, for example, the technological process can be halted or the operational parameters changed, thereby improving overall efficiency.

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54. Hwang, B.H. and M.R. Lee. 2000. Solid-phase microextraction for organochlorine pesticide residues analysis in Chinese herbal formulations. J. Chromatogr. A 898: 245–256. 55. Evans, T.J., C.E. Butzke, and S.E. Ebeler. 1999. Analysis of 2,4,6-trichloroanisole in wines using solidphase microextraction coupled to gas chromatography mass spectrometry. J. Chromatogr. A 786: 293–298. 56. Mestres, M., M.P. Marti, O. Busto, et al., 2000. Headspace solid phase microextraction of higher fatty acid ethyl esters in white rum aroma. J. Chromatogr. A 881: 583–590. 57. Mestres, M., O. Busto, and J. Gausch. 2000. Analysis of organic sulfur compounds in urine aroma. J. Chromatogr. A 881: 569–581. 58. Fitzgerald, G., K.J. James, K. MacNamara, and M.A. Stack. 2000. Characterization of whiskeys using solid-phase microextraction with gas chromatography-mass spectrometry. J. Chromatogr. A 896: 351–359. 59. Augusto, F., A.S. Pires Valente, T.E. dos Santos, et al. 2000. Screening of Brazilian fruit aromas using solid-phase microextraction-gas chromatography-mass spectrometry. J. Chromatogr. A 873: 117–127. 60. Ligor, M. and B. Buszewski. 1999. Determination of menthol and menthone and pharmaceutical products by solid-phase microextraction-gas-chromatography. J. Chromatogr. A 847: 161–169. 61. Fernandez, M., C. Padron, and L. Marconi. 2001. Determination of organophosphorus pesticides in honeybees after solid-phase microextraction. J. Chromatogr. A 922: 257–265. 62. Hwang, B.H. and M.R. Lee. 2000. Solid-phase microextraction for organochlorine pesticide residues analysis in Chinese herbal formulations. J. Chromatogr. A 898: 245–256. 63. Eisert, R., S. Jackson, and A. Krotzky. 2001. Application of on-site solid-phase microextraction in aquatic dissipation studies of profoxydim in rice. J. Chromatogr. A 909: 29–36. 64. Zambonin, C.G. 2003. Coupling solid-phase microextraction to liquid chromatography. A review. Anal. Bioanal. Chem. 375: 73–80. 65. Bagheri, H. and A. Salemi. 2004. Coupling of a concentric in-two-tube solid phase microextraction technique with HPLC-fluorescence detection for the ultratrace determination of polycyclic hydrocarbons in water samples. Chromatographia 59: 501–505. 66. Baltussen, E., P. Sandra, F. David, et al. 1999. Stir bar sorptive extraction (SBSE), a novel extraction technique for aqueous samples: Theory and principles. J. Microcolumn Sep. 11: 737–747. 67. Kolahgar, B., A. Hoffmann, and A.C. Heiden. 2002. Application of stir bar sorptive extraction to the determination of polycyclic aromatic hydrocarbons in aqueous samples. J. Chromatogr. A. 963: 225–230. 68. Ochiai, N., K. Sasamoto, H. Kanda, et al. 2008. Sequential stir bar extraction for uniform enrichment of trace amounts of organic compounds in water sample. J. Chromatogr. A 1200: 72–79. 69. Blasco, C., G. Font, and Y. Pico. 2002. Comparison of microextraction procedures to determine pesticides in oranges by liquid chromatography-mass spectrometry. J. Chromatogr. A 970: 201–212. 70. David, F., B. Tienpont, and P. Sandra. 2003. Stir-bar sorptive extraction of trace organic compounds from aqueous matrices. LC-GC Europe 16: 14–16. 71. Lipinski, J. 2000. Automated multiple solid phase micro extraction. An approach to enhance the limit of detection for the determination of pesticides in water. Fresenius J. Anal. Chem. 367: 445–449. 72. Sandra, P., B. Tienpont, and J. Vercammen. 2001. Stir bar sorptive extraction applied to the determination of dicarboximide fungicides in wine. J. Chromatogr. A 928: 117–126. 73. Kende, A., Z. Csizmazia, T. Rikker, et al. 2006. Combination of stir bar sorptive extraction—retention time locked gas chromatography-mass spectrometry and automated mass spectral deconvolution for pesticide identification in fruits and vegetables. Microchem. J. 84: 63–69. 74. Liu, W., Y. Hu, J. Zhao, et al. 2005. Determination of organophosphorus pesticides in cucumber and potato by stir sorptive extraction. J. Chromatogr. A 1095: 1–7. 75. Roy, G., R. Vuillemin, and J. Guyomarch. 2005. On-site determination of polynuclear aromatic hydrocarbons in sea water by stir bar extraction (SBSE) and thermal desorption (GC-MS). Talanta 66: 540–546. 76. Popp, P., C. Bauer, and L. Wennrich. 2001. Application of stir bar sorptive extraction in combination with column liquid chromatography for the determination of polycyclic aromatic hydrocarbons in water samples. Anal. Chim. Acta 436: 1–9. 77. Hu, Y., Y. Yang, and J. Huang. 2005. Preparation and application of poly(dimethylsiloxane)/β-cyclodextrin solid-phase microextraction membrane. Anal. Chim. Acta 543: 17–24. 78. Basher, C., A. Parthiban, A. Jayaraman, et al. 2005. Determination of alkylphenols and bisphenol-A. A comparative investigation of functional polymer-coated membrane microextraction and solid-phase microextraction techniques. J. Chromatogr. A 1087: 274–282.

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15

Chemometrics as a Tool for Treatment Processing of Multiparametric Analytical Data Sets Stefan Tsakovski and Vasil Simeonov

CONTENTS 15.1 Introduction ...................................................................................................................... 15.2 Basic Chemometric Methods ............................................................................................ 15.2.1 Cluster Analysis .................................................................................................... 15.2.1.1 Theoretical Principles ............................................................................ 15.2.1.2 Case Study (Struma River) .................................................................... 15.2.2 Self-Organizing Maps .......................................................................................... 15.2.2.1 Theoretical Principles ............................................................................ 15.2.2.2 Case Study (Struma River) .................................................................... 15.2.3 Principal Component Analysis ............................................................................. 15.2.3.1 Theoretical Principles ............................................................................ 15.2.3.2 Case Study (Struma River) .................................................................... 15.2.4 Receptor Modeling (PCA with Multiple Linear Regression Analysis) ................ 15.2.4.1 Theoretical Considerations .................................................................... 15.2.4.2 Case Study (Struma River) .................................................................... 15.3 Conclusions ....................................................................................................................... Acknowledgment ....................................................................................................................... References ..................................................................................................................................

369 370 370 370 373 376 376 377 380 380 382 383 383 385 385 386 386

15.1 INTRODUCTION In the last three decades chemometrics has undergone enormous development as a result of the ever greater attention accorded by scientists to environmental data treatment, intelligent instrument signal interpretation, the design and optimization of analytical procedures, and, last but not least, the new metrological aspects of the methods and procedures of analysis. However, it is our deep conviction that the pathways and the effects of numerous polluting species in all environmental compartments have turned out to be the most specific reason for the predominant application of chemometrics in the environmental research field. The opportunities offered by chemometric approaches to classify, model, and reliably interpret large, multiparametric data sets (delivered mainly by the procedures for the environmental monitoring of water, air, and soil) are indeed remarkable. 369

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Modern chemometrics exploits the capabilities of multivariate statistics, already regarded as the classical approach, but also newer, less common methods. It is generally assumed that welldeveloped and very widely applied basic methods such as cluster analysis (CA), principal components analysis, discriminant analysis, and neuron net approaches are entirely sufficient to cover the main objectives of chemometrics as novel multiparametric information tools helping to acquire a better understanding of the information hidden in large data sets. With their aid one can perform effective data mining, exploratory data analysis, and intelligent data analysis in order to achieve the satisfactory classification, dimension reduction, projection, and appropriate modeling of principally complex objects described by many chemical, physical, and biological variables (or parameters). The undoubted advantage of data interpretation and modeling by the use of chemometric methods has been thoroughly demonstrated by a large number of case studies relating to different locations, time periods, and environmental compartments. It has become accepted that environmental quality assessment achieved by chemometrics is the only reliable basis for decision-making in critical situations and the most helpful instrument for solving problems at different levels of responsibility. According to its already classical definition, chemometrics is a branch of modern analytical chemistry that involves the application of mathematical, statistical, and other methods employing formal logic • To evaluate and to interpret chemical and analytical data. • To optimize and to model chemical and analytical processes and experiments. • To extract a maximum of chemical and analytical information from complex data sets. Chemometric methods are traditionally divided into • Unsupervised multivariate statistical methods [CA, principal components analysis, Kohonen’s self-organizing maps (SOMs), nonlinear mapping, etc.], which perform spontaneous data analysis without the need for special training (learning), levels of knowledge, or preliminary conditions. • Supervised (learning) methods where a priori information is needed, for example, demarcation of a certain number of classes in the classification process. The main goal of this chapter is to present the theoretical background of some basic chemometric methods as a tool for the assessment of surface water quality described by numerous chemical and physicochemical parameters. As a case study, long-term monitoring results from the watershed of the Struma River, Bulgaria, are used to illustrate the options offered by multivariate statistical methods such as CA, principal components analysis, principal components regression (models of source apportionment), and Kohonen’s SOMs.

15.2 BASIC CHEMOMETRIC METHODS 15.2.1 CLUSTER ANALYSIS 15.2.1.1 Theoretical Principles The notion of CA or clustering incorporates a broad class of methods used to classify variables (usually chemical components) or objects (usually sampling locations) into groups. This exploratory approach is very useful for revealing and displaying the structure of the data investigated. In this respect, CA is an exploratory, unsupervised pattern cognition technique that does not need a priori knowledge about the investigated objects.1,2

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371

In environmental studies, responses to the following questions are frequently required: • What are the factors controlling the data structure obtained? • Which is the proper set of variables for reliable environmental modeling? • What is the optimal monitoring scheme? For an appropriate modeling approach and source assessment, we need correct answers to these questions: this makes exploratory data techniques such as CA a necessary preliminary step prior to undertaking modeling studies. Two big families of clustering algorithms can be distinguished: hierarchical and nonhierarchical ones. Hierarchical clustering can be performed in an agglomerative and in a divisive way. At the beginning of the agglomerative procedure each object is located in a separate cluster. In the agglomerative algorithms the aims are to combine similar objects into a cluster, add objects to an already formed “closest” cluster, or combine similar clusters. The divisive algorithms, on the other hand, start with one single cluster containing all the objects and then, step by step, the most “inhomogenous” ones are stripped away to form smaller, “more homogenous” clusters. The hierarchical clustering output is a tree-like diagram called a dendrogram. The aim of classification by nonhierarchical clustering is to classify the objects under consideration into a certain number of preliminary intended clusters. The clusters are formed simultaneously by partitioning methods, which allow the objects to be rearranged between the clusters. The main disadvantage of nonhierarchical clustering is the absence of a graphical output. The most commonly used procedures in environmental studies are clustering performed using hierarchical agglomerative procedures because of the comprehensible graphical output and clear “hierarchical” relations between clusters.2,3 In CA the input data matrix X (measurement data) is presented as Ê x11 Áx 22 X=Á Á Á Ë xn1

x12 x22  xn 2

 x1m ˆ  x2 m ˜ ˜, xij  ˜ ˜  xnm ¯

(15.1)

where n is the number of objects and m their variables. Usually the data are autoscaled by the following z-transformation formula to avoid the influence of dimension on classification:

zij =

xij - x j , sj

(15.2)

where xj =

1 2

n

Âx

ij

i =1

and sj =

1 n -1

n

Â(x

ij

- x j )2 .

i =1

To find the structures of the objects in the data set, we need a measure of similarity. Although many types of measures can be applied, the Euclidean distance is the most frequently used similarity measure. According to the law of Pythagoras, the distance between two points O1 and O2 characterized by variables x and y can be presented as follows (Figure 15.1): d (O1 ,O2 ) = ( y1 - y2 )2 + ( x1 - x2 )2 .

(15.3)

372

Analytical Measurements in Aquatic Environments y y1

O1 (x1, y1)

d

a

y2

O2 (x2, y2)

b

x1

FIGURE 15.1

x2

x

Distance between two objects in two-dimensional (2D) space.

The extension to more than two dimensions is given by the Euclidean distance and the distance between two objects, i and k, and can be written as m

d (i, k ) =

 (x

ij

- xkj )2 ,

(15.4)

j =1

where m is the number of variables (dimensions). Then a similarity matrix is calculated, which includes all the distances between the objects to be classified. The matrix is symmetrical with zero values on the main diagonal: Ê 0 Ád D = Á 21 Á Ád Ë n1

d12 0  dn 2

d13  d23    dn 3 

d1n ˆ d2 n ˜ ˜. ˜ 0 ˜¯

(15.5)

There is a wide variety of hierarchical algorithms, but the typical ones include the single linkage, complete linkage, and average linkage methods. In the similarity matrix one seeks out the two most similar, linked objects p and q (with the smallest distance Dqp) in order to start constructing the dendrogram. The process is repeated until all the objects are linked in the hierarchical classification scheme. In principle, the most similar objects are considered to form a new object p* out of these two. In this way, the similarity matrix is reduced by one column and one row. In average linkage, the similarities between the new object and the rest are obtained by averaging the similarities of the two most similar objects with the others (e.g., Dip* = (Diq + Dip)/2). In single linkage, Dip* is the distance between some object i and the nearest of the linked objects, that is, Dip* is equal to the smaller of the two distances Diq and Dip. In complete linkage, the opposite rule is obtained: Dip* is the distance between object i and the most remote object q or p. Thus, the only difference in the different hierarchical clustering algorithms is the way in which the linkage sequence is determined. Generally, average linkage is the preferred procedure for larger data sets. However, the above-mentioned algorithms are not to be recommended, because they often form inversions, mainly because of space

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reduction. Special attention should be paid to Ward’s method of clustering: This is based on a heterogeneity criterion defined as the sum of the squared distances of each member of a cluster to the centroid of that cluster. The objects and clusters are joined on the basis of the criterion that the sum of the heterogeneities of all clusters (formed in the next step) should increase as little as possible. In general, Ward’s method is space conserving and seems to give better results. If squared Euclidean distances are used as a similarity measure, Ward’s method also tends to optimize the data set variance.2-4 As classification results depend on the clustering procedure, it is highly recommended that CA be combined with display methods like principal component analysis (PCA).3,4 15.2.1.2 Case Study (Struma River) The Struma River is located in the southern part of Bulgaria. It flows from north to south and has a length of 290 km as far as the Greek border. From that point to the Aegean Sea the river is about 110 km long. Its total watershed in Bulgaria is nearly 10,250 km2 and covers the Vitosha Mountains and the Rila, Pirin, and surrounding mountains (Figure 15.2). Being a crossborder river, the Struma basin is of substantial importance to both Bulgaria and Greece. That is why the careful monitoring of water quality in the long or short term at different sampling sites is not only an ecological but also a political issue. Figure 15.2 shows a map of the Struma in Bulgaria along with the locations of the sampling sites from the Struma River monitoring network controlled by the Ministry of Environment and Waters. The monitoring system covers a large number of sites where water quality is tested regularly on a daily, weekly, or monthly basis. The industrial and agricultural activity in the Struma River basin is relatively great. The population of this basin is 532,000 (6.47% of the population of Bulgaria) with nearly 300,000 (71%) in urban areas. The main towns (populations >20,000) are Pernik, Blagoevgrad, Kyustendil, Dupnitsa, Petrich, and Sandanski. As far as land use is concerned, some 29,700 ha of land is under irrigation and the natural conditions in this region favor the cultivation of vegetables, fruits, tobacco, cotton, and almonds. The water in the basin is used for irrigation and the

Breznik Kowrta R

Sofia

ROMANIA

120 Pernik 398 119 296 399 293 297 Struma R 298 Dmgonhuri R Zeme 131 Bobovdol Bistritsa R Kjusten R Sapareva 125 dib German R 402 Banja 299 Dupnica 40 126 Rusta R Boboseva 122 Rila

SERBIA & MONTENEGRO

BULGARIA Sofia

Varna Nesebur

White Burka R

Struma R

Blagoevgra 127 d Simitli 123

TURKEY

GREECE MACEDONIA

Black sea

Aegean sea

Sea of Marmara

Kresn a Strdmjan

Lebnka R

distance scale 0

FIGURE 15.2

N

30 km

Sandanski 403y 471 301 Sirwesnica R 124 Petrik

Location of monitoring points on the Struma River (Bulgaria).

Legend: Major city Sampling point Border

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production of electricity. Electricity is generated at power stations (Kalin, Kamenitsa, Pastra, Rila, and others) on some of the Struma’s tributaries. There are just a few sites where there is industrial activity: sites 120, 296—steel works, food industry, and coal mining; site 125—agricultural activity and local food industry; site 122—coal mining; site 127—food industry, coal mining, and metal manufacturing; site 123—coal mining; and site 403—food industry. There are also several uncompleted irrigation systems: the Dolna Dikanya–Kovachevzi–Radomir schemes, which are intended to use water from the Pchelin reservoir; the Dyakovo–Dupnitsa scheme should use water from the Dyakovo reservoir. At present, the Pirinska Bistritsa irrigation system is in the process of reconstruction and modernization. The data set used for the exploration of multivariate methods consists of more than 15,000 measurements on the Struma River. The sites chosen almost completely cover the length of the river from its source to the Greek border. Water samples were collected between 1989 and 1998. For three locations the data set included seven complete years of measurements (provisionally denoted as 3–7: number of sampling locations–number of years of measurements). For the other locations this relationship was as follows: 3–6, 6–5, 1–4, 9–2, and 1–1. The chemical indicators involved were pH, dissolved oxygen (O2) (mg O2 L -1), oxidation ability (OXIS) (mg O2 L -1), biological oxygen demand (BOD) (mg O2 L -1), chemical oxygen demand (COD) (mg O2 L -1), dissolved matter (DISS) (mg L-1), -1 nondissolved matter (N-DISS) (mg L-1), chloride (Cl-) (mg Cl L -1), sulfate (SO24 ) (mg S-SO4 L ), + -1 -1 ammonium (NH 4 ) (mg N-NH4 L ), nitrate (NO 3 ) (mg N-NO3 L ), nitrite (NO2 ) (mg S-SO4 L -1), iron (Fe2+) (mg Fe L -1), and calcium (Ca2+) (mg Ca L -1). The chemical analyses were performed according to standard analytical methods as routinely applied in the monitoring network’s laboratories. Potentiometry, titrimetry, gravimetry, and spectrophotometry are the standard methods used in surface water quality analysis, especially for major indicators like those mentioned above. Sample preparation and sample measurements are described in detail elsewhere.5 CA indicates three clusters of variables according to the less restrictive criterion of Sneath’s index of cluster significance (2/3 of Dmax, where Dmax is the maximum distance): NO2 and O2; Fe2+, + 2+ SO24 , NH 4 , N-DISS, COD, OXIS, and BOD; and Cl , NO3 , DISS, Ca , and pH (Figure 15.3). Interpretation of the hierarchical dendrogram for the clustering of chemical variables shows clearly that three major clusters are formed. One of them shows up the close relation between nitrite content and oxygen content in the river water. This is an important indicator regarding the processes involving oxygen demand and oxidation, which are important in biological transformations. The

Ward’s method, squared Euclidean distance 120

100*Dmax/Dmax

100 80 Sneath’s index—2/3 Dmax 60 40

FIGURE 15.3

pH

Ca

DISS

Cl

NO3

BOD

COD

OXIS

NH4

N-DISS

Fe

Classification of variables.

SO4

O2

0

NO2

20

Chemometrics as a Tool for Treatment Processing of Multiparametric Analytical Data Sets

375

second cluster involves iron, sulfate, ammonium, nondissolved solids, COD, oxidation ability, and BOD, that is, again parameters representing mainly oxidation processes in the water body that are related directly to anthropogenic activity. The last cluster contains chloride, nitrate, dissolved oxygen, calcium, and pH: these are the parameters that determine the hardness and acidity of water. Using the CA dendrogram (Figure 15.4) to assess the similarity patterns in the space of the sampling locations is a complex task. The dendrogram shows that all the monitoring locations can be generally grouped into two main clusters (I¢ and II¢) according to the less restrictive significance criterion of Sneath’s index (2/3 of Dmax) or four clusters (I–IV) according to the more restrictive one (1/3 of Dmax). As already mentioned, the interpretation of the dendrogram for linking the sampling locations (including their time parameters) is quite a complicated task, especially in the case of large numbers of data. In this case study, four major clusters should be considered. Careful inspection of the content of each cluster, however, suggests the following explanation: Cluster I: This contains mostly sampling sites located in urban environments (with provisional numbers 122, 123, and 126), which are characterized by elevated values of BOD and COD, chlorides, sulfates, calcium, and ammonium. Such site discrimination allows this cluster to be ascribed to the provisional “urban site location” pattern. In principle, these are sites with elevated levels of anthropogenic pollution. Cluster II: This includes mostly sites located on the main tributaries (398, 399, and 403) of the Struma River and has therefore been provisionally named the “tributary” pattern. Here, the concentrations of chlorides, nitrates, calcium, and ammonium are low, and site

Ward’s method, squared Euclidean distance 400 98 01 301–97–02 127–97–04 123–92–06 123–98–10 123–95–12 126–92–03 122–93–08 121–98–01 293–97–02 293–98–06 400–97–05 124–95–01 122–92–10 403–98–05 398–95–02 398–98–05 299–98–04 298–97–11 122–98–04 122–95–07 121–91–03 121–97–12 297–97–04 299–93–03 124–94–03 297–93–05 398–93–11 126–97–04 123–94–10 125–95–09 299–97–01 126–93–09 298–97–10 127–93–10 127–94–08 127–90–09

I

2/3Dmax

1/3Dmax I′

II

III

II′ 0

20 IV

40

60 100*D/Dmax

FIGURE 15.4

Classification of sampling locations.

80

100

120

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discrimination is based on elevated concentrations of nitrite and total oxygen. These sampling sites indicate a lower anthropogenic impact and an enhanced biological (natural) impact. Cluster III: This group of sites forms the “rural” pattern of sampling locations (predominantly sites 297 and 299), where the concentrations of the chemical variables are on an intermediate level with respect to both anthropogenic and natural impacts. Cluster IV: This is a relatively small cluster, which reflects the behavior of a background site (127) with the lowest levels of all the chemical and physicochemical parameters measured. In summary, CA enables a large data set (over 1100 monitoring results) to be classified into four major site patterns. They are related to the geographical positions of the sampling sites and facilitate the optimization of the whole monitoring process; for instance, instead of sampling each site in the monitoring network, a rapid monitoring procedure selects a representative from each separate pattern in order to make decisions or solve problems along in the watershed.6-8

15.2.2 SELF-ORGANIZING MAPS 15.2.2.1 Theoretical Principles The SOM is an algorithm used to visualize and interpret large high-dimensional data sets9; it is an unsupervised pattern cognition method similar to CA. The main advantage of SOM is the simultaneous classification of variables and objects (sampling locations). Typical applications are visualizations of process states or financial results by representing the central dependencies within the data on the map. The map consists of a regular grid of processing units called neurons (Figure 15.5). A model of some multidimensional observations, possibly a vector consisting of features (variables), is associated with each unit. The map attempts to represent all available observations with optimal accuracy using a restricted set of models. At the same time the models become ordered on the grid so that similar models are close to each other and dissimilar models far from each other. Fitting of the model vectors is usually carried out by a sequential regression process, where t = 1, 2, . . . is the step index. For each sample x(t), the winner index c (best matching unit—BMU) is first identified by the condition "i,  x(t) - mc(t)  £  x(t) - mi(t) .

Objects

Grid of neurons

FIGURE 15.5

SOM architecture.

(15.6)

Chemometrics as a Tool for Treatment Processing of Multiparametric Analytical Data Sets

X BMU

377

X Input object BMU at step t BMU at step t+1

FIGURE 15.6

Updating the BMU and its neighbors toward the input object.

When the BMU has been found, the weight vectors of the SOM are updated so that the BMU is moved closer to the input vector in the input space (Figure 15.6). Then, all the model vectors or a subset of them belonging to the nodes centered around node c = c(x) are updated as mi(t + 1) = mi(t) + hc(x),i(x(t) - mi(t)).

(15.7)

Here, hc(x),i is the “neighborhood function,” a decreasing function of the distance between the ith and cth nodes on the map grid. This regression is usually reiterated over the available objects. The trained map can be graphically presented by 2D planes for each variable, with the variable distribution values being indicated by different colors on the different regions of the map. Additionally, the node “coordinates” (vectors) can be clustered by the nonhierarchical K-means classification algorithm. 15.2.2.2 Case Study (Struma River) The data set from the previous case study, in which the data were interpreted by clustering, is now treated using the SOM approach. In the first step, the classification of variables was tried. The ordering of 2D SOM planes (Figure 15.7) indicates a high similarity of OXIS, BOD, COD, N-DISS, and NH 4+. The O2 and NO2group is located near the aforementioned variables, which indicates a high level of similarity. Visible differences in the gray-scale filled pattern suggest the existence of inversely proportional correlations between O2, and NO2- on the one hand, and OXIS, BOD, COD, N-DISS, and NH 4+ on the other. These two groups include all the “oxygen-connected” variables and reveal links between the parameters responsible for the oxygen content of the water body (O2, COD, BOD, and OXIS) and the various biological processes in the water. Dissolved oxygen levels are considered to be the most important indicator of a water body’s ability to support aquatic life. COD is commonly used as an indirect measure of the oxygen required to oxidize all compounds, both organic and inorganic, in water. BOD reflects the amount of oxygen consumed by the biological processes that break down organic matter in water. A third, clearly distinguished, group of similar variables consisting of Cl-, DISS, and NO 3- represents human activity in the Struma River basin. This last group, not marked in Figure 15.7, can be recognized as a link between pH, and Fe2+ and Ca; it is not interpretable in such a simple way, as it includes acidity and hardness components.

378

Analytical Measurements in Aquatic Environments OXIS

BOD

COD

N-DISS

NH4

O2

NO2

SO4

Cl

DISS

NO3

FIGURE 15.7

pH

Ca

Fe

Classification of variables.

The SOM visualization is in good agreement with the CA results. Minor differences are related mainly to the linkage or the lack of linkage between pH and Fe2+ in the CA and SOM algorithms. CA attributes Fe2+ and pH to different clusters because of their negative correlation. Similar considerations can be ascribed to the position of SO 24 , which in SOM has the position of an “outlier.” The visualization abilities of CA and SOM are clearly comparable, but SOM has three additional advantages: • The projection of variables’ similarity also contains semiquantitative information about the distribution of a given chemical parameter in the space of the sampling locations. • SOM visualization is able to present similarity between both positively and negatively correlated variables. • SOM visualization can indicate “outliers,” that is, those chemical variables or sampling locations that do not belong to a well-organized group. One advantage of hierarchical CA over SOM is the clear “hierarchical” relation between clusters and the possibility of interpreting more than one classification scheme. In the next step, the similarity between the sampling sites was investigated using SOM. Different values of k (a predefined number of clusters) were tried and the sum of squares for each run was calculated. Finally, the best classification with the lowest Davies–Bouldwin index (also shown graphically in Figure 15.8) was chosen. It is seen that the five-cluster configuration has the lowest

Chemometrics as a Tool for Treatment Processing of Multiparametric Analytical Data Sets

379

1.35

Cluster I

Davies–Bouldwin index value

1.3

1.25

Cluster II

Cluster V 1.2 Cluster IV Cluster III 1.15

1.1

FIGURE 15.8

0

2

4 6 8 Number of clusters

10

Classification of sampling locations.

index. For monthly averages, the dimensionality of the Kohonen map was 10 ¥ 17, and it is clear that more than one case from the initial data set (1104) was related to a particular unit (hexagon). Cases included in each hexagon were grouped in agreement with cluster borders. The SOM classification obtained was then compared with the real data from the initial data set (all sites, all measurements, and monthly averages). Setting up the real values (mean value and SD) of the chemical indicators along with the classification results enabled a fairly reasonable interpretation to be obtained of the clustering pattern (Equation 15.8) connected with the water quality of the Struma River. Clusters I–V contain different numbers of cases out of the total of 1104: I–412, II–261, III–49, IV–101, and V–281. In general, clusters III and IV are linking cases characterized by increasing values of BOD and OXIS as well as increasing concentrations of Cl-, SO42-, Ca2+ , and NH4+ , in parallel with decreasing levels of O2, NO 2-, and pH. In contrast, clusters I, II, and V include sites characterized by elevated levels of O2 and NO 2-. Clusters IV and V contain sites having the highest content of DISS as well as the highest NO3- concentration. SOM clustering yields a number of clusters (five) similar to the number of clusters indicated by CA (four) according to the more restrictive criterion of Sneath’s index (1/3 of Dmax). This small difference may be due to the fact that the squared Euclidean distance was used to measure similarity among clusters in CA, whereas the Euclidean distance was applied in SOM. Detailed analysis of the variation of chemical indicators across clusters gives the impression that five clusters contain two distinctive patterns of sampling locations, which can be designated as “nonpolluted” (clusters I, II, and V) and “polluted” (clusters III and IV). This is in agreement with clustering using the less restrictive criterion of Sneath’s index (clusters I¢ and II¢). It is easy to show the statistical significance of the differences between the monthly mean values of the variables between particular clusters using the nonparametric Kruskal–Wallis and Mann–Whitney U tests. This comparison is omitted here, however, because of the univariate nature of these procedures.

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Analytical Measurements in Aquatic Environments

15.2.3 PRINCIPAL COMPONENT ANALYSIS 15.2.3.1 Theoretical Principles There are different variants of PCA, but basically one feature they all have in common is that they produce linear combinations of the original columns in a data matrix (data set) responsible for describing the variables characterizing the objects of observation. These linear combinations represent a type of abstract measurement [factors and principal components (PCs)] that is a better descriptor of the data structure (data patterns) than the original (chemical or physical) measurements. Usually, the new abstract variables are called latent variables, and they differ from the original ones (called manifest variables). It is a common finding that just a few of the latent variables account for a large part of the data set variation. Thus, the data structure in a reduced space can be observed and studied. Generally, when analyzing a data set (matrix) X consisting of n objects for which m variables have been measured, PCA can extract s PCs (factors or latent variables) where s < m: Ê x11 Áx Á 21 Á Áx Ë m1

x12 x22  xm 2

 x1n ˆ Ê a11  x2 n ˜ Á a21 ˜ =Á  ˜ Á   xmn ˜¯ ÁË am1

   

a1s ˆ Ê f11 a2 s ˜ Á f21 ˜ ¥Á ˜ Á ams ˜¯ ÁË fs1

f12  f1n ˆ Ê e11 f22  f2 n ˜ Á e21 ˜ +Á   ˜ Á  fs 2  fsn ˜¯ ÁË em1

e12 e22  em 2

   

e1n ˆ e2 n ˜ ˜ , (15.8) ˜ emn ˜¯

X = A ¥ F + E, where X is the data matrix, A is the factor loadings matrix, F is the factor scores matrix, and E is the residual matrix produced by the loss of information because of dimension reduction. PC 1 represents the direction in the data containing the largest variation. PC 2 is orthogonal to PC 1 and gives the direction of the largest residual variation around PC 1. The next PCs follow this rule. It is important to note that all PCs are uncorrelated. Figure 15.9 shows a graphical presentation of the first two PCs.

X2 PC 1

PC 2

X1

FIGURE 15.9

Graphical presentation of PC 1 and PC 2 in 2D space.

Chemometrics as a Tool for Treatment Processing of Multiparametric Analytical Data Sets 3

4

381

III

12 10 13

3

16 4

PC 2

2

1 11 78 6 14 8 5 19 27 15 18 29 22 33 20 22

1 0

–1

I 39 34 II 35 37 33 31

36

37 38

–2 –2

0

2

4

6

8

PC 1

FIGURE 15.10

Score plot PC 1 versus PC 2.

The projections of the data on the plane of PC 1 and PC 2 can be computed and shown on a biplot (Figure 15.10). Known as a score plot, such a plot enables the similarity of groups of objects to be determined and classification trends to be detected.1-4 PCA makes it possible not only to analyze relationships among objects (e.g., sampling sites or periods in environmental monitoring studies) but also to reveal relationships between variables. According to PCA theory, the scores on the PCs (the new coordinates of the data space) are the weighted sum of the original variables (e.g., chemical and physical measurements): Score (value of object k along the PC p) = a1pv1 + a2pv2 + . . . + ampVm, where V denotes the variable value (e.g., concentration) and a represents the weights containing information about the variables. This score can be written for each of the PCs considered in a study. These weights are called loadings. Thus, the scores are linear combinations of the manifest variables. The information present in the loadings can also be displayed in respective loadings plots (Figure 15.11).

0.4 Zn

Cr

Mn

0.0 Co

Ni

Cd

Cu Fe

PC 3

–0.4

–0.8 As

0.8

Pb PC

0.4 2

0.8

0.0 –0.4 –0.4

FIGURE 15.11

0.0

Loadings plot (PC 1 versus PC 2 versus PC 3).

0.4 PC 1

1.2

382

Analytical Measurements in Aquatic Environments 7 6

Eigenvalue

5 4 3 2 PC 3 1 0

FIGURE 15.12

1

2

3

4 5 6 7 Number of PCs

8

9

10

Scree plot.

These plots reveal important information about correlations and relationships among variables. The factor loadings also represent the relations between “old” variables and new latent variables. Factor loadings with absolute values equal to or higher than 0.7 are indicative of a strong association. Loadings between 0.4 and 0.7 are indicative of a moderate “participation” of initial variables in a PC. Factor loadings lower than 0.4 indicate that the variables are not associated with the PCs. The factor loadings of manifest variables are an indication of the origin of extracted PCs and provide important information on “hidden” factors that determine data set structure. It is also worth mentioning that the correct application of PCA very often requires scaling of the input data in order to eliminate dependence of the analytical results on the scale of the original variables. One of the key aspects of PCA analysis is the question of how many PCs should be retained. There are certain recommendations that are sometimes contradictory: • Retained PCs should explain at least 70% of data set variation. • Retained PCs should have eigenvalues higher than 1 (i.e., PCs accounting for a greater amount of variance than one original variable). • The number of retained PCs should be assessed by the scree test. The last approach is widely used for practical data exploration and yields a biplot in which PC eigenvalues are plotted against PC numbers (Figure 15.12). Usually the PCs retained are those on the slope of the graph before the decrease in eigenvalues levels off to the right of the plot. In the example presented, three PCs can be retained according to the scree test. It is very important in environmental studies to identify the “nature” of a PC. A retained PC that does not represent “real” anthropogenic or natural factors governing an environmental system is useless and does not provide any useful information about the data set under scrutiny. 15.2.3.2 Case Study (Struma River) The data set treated in this study is a part of the above-mentioned measurements in the Struma River basin. The period of observation in this region was 10 years (1989–98), and the chemical indicators were pH, dissolved oxygen, BOD5, COD, conductivity, acidity, DISS, N-DISS, total hardness, chloride, sulfate, ammonium, nitrate, nitrite, iron, magnesium, and calcium. Four latent parameters (factors or PCs) explain a substantial part of the total variation of the set (the variance explained by all four PCs is about 79%; Table 15.1). The first factor could be provisionally

Chemometrics as a Tool for Treatment Processing of Multiparametric Analytical Data Sets

383

TABLE 15.1 Factor Loadings (Only Statistically Significant Figures are Given) Variables pH O2 BOD COD DISS N-DISS

PC 1

PC 2

PC 3

PC 4 0.65

0.76 0.86 0.86 0.94

Cl-

0.76 0.93

SO42-

0.88

NH 4+

0.74

NO2-

0.62

NO3-

0.87 0.76

Fe3+ Ca2+

0.92

Mg2+ Hardness Explained variance (%)

0.87 0.65 21.74

32.52

14.87

9.72

named “anthropogenic.” It consists of chemical components that are related to the products of human activity such as dissolved oxygen, BOD5, free acidity, suspended matter, chloride, ammonium, and sulfate. The significance of this latent parameter for water quality is quite high as it explains over 30% of the total variance of the system. The second latent factor is probably of natural origin and is provisionally termed “water hardness.” It contains the chemical parameters responsible for water hardness, that is, calcium, magnesium, and the total hardness parameter itself and, in addition, DISS. The third latent factor is related to the content of nitrite, nitrate, and iron, but also to the COD. This factor is termed “biological” since these parameters are predominantly linked to biological activity. Related as it is to the pH value of the water, this last factor has been provisionally named “acidity.” This chemometric procedure is of considerable importance in identifying the data set structure, as it reveals hidden factors (sources of pollution or natural sources) that are important for the data set structure.

15.2.4 RECEPTOR MODELING (PCA WITH MULTIPLE LINEAR REGRESSION ANALYSIS) 15.2.4.1 Theoretical Considerations In many chemical studies, the measured properties of the system can be regarded as the linear sum of the fundamental effects or factors in that system. The most common example is multivariate calibration. In environmental studies, this approach, frequently called receptor modeling, was first applied in air quality studies. The aim of PCA with multiple linear regression analysis (PCAMLRA), as of all bilinear models, is to solve the factor analysis problem stated below: p

xij =

Âa

f + eij ,

ik kj

(15.9)

k =1

where xij is the ith elemental concentration in the jth sample, aik is the contribution to the concentration of the ith element from the kth factor (source), f kj is the elemental concentration from the kth source, and eij denotes residuals unexplained by the model. This model was first described by

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Analytical Measurements in Aquatic Environments

Thurston and Spengler.10 Originally used to model mainly aerosol data, it is now the most widely used receptor model in environmental studies and is applied to water studies as well. The main advantage of PCA-MLRA is that PCA provides unique solutions to the system, and the interpretation of the variance results is straightforward since factor scores and loadings are forced to be orthogonal (in order to explain the maximum variance). Therefore, pollution sources can be interpreted directly from the factor scores and loadings. The main drawback, however, is that solutions may not always have a direct physical interpretation, as negative factor scores may be obtained. The fact that PCA searches for a linear combination of factors (sources) to fulfill the orthogonality constraints implies that the solutions have good mathematical properties but may not always have a physical meaning. A number of solutions are generally applied in order to correct for negative scores, such as rotation of PCA factor matrices to simplify interpretation as in the Varimax orthogonal rotation, scores uncentering (to make them positive by introducing a “zero day”), and regression to total sample mass.10 The methodology of PCA-MLRA is described step by step as follows: Step 1. PCA is usually performed as the Varimax orthogonal rotation of PCs. This rotation gives a more straightforward interpretation of extracted PCs by increasing higher factor loadings and decreasing lower ones. Step 2. Introducing a “zero day” for each variable: – (0 = Ci) (Z 0)i = _______ . (15.10) Si Step 3. Calculating the absolute zero PC score for each PC: n

F0 p =

ÂB

pj

( Z 0 )i ,

(15.11)

i =1

where Bpj is the factor score coefficient matrix produced by performing PCA. It is related to the factor loadings matrix A:B = A/li, where li are the eigenvalues of the extracted PCs. Step 4. Calculating the absolute PC score for each PC:

[APCS]p ¥ j = [F]p ¥ j - [F0]p ¥ j .

(15.12)

Step 5. Performing MLRA where the absolute PC scores (APCS) are independent variables (descriptors) and the sum of measured concentrations is a dependent variable: p

Mj = z 0 +

 z APCS , k

kj

(15.13)

k =1

where Mj is the total concentration in observation j, zk APCSkj is the concentration identified with source k, and z0 is the concentration due to sources unaccounted for in the PCA. Step 6. Performing MLRA where the concentrations identified with sources are independent variables and each elemental concentration is a dependent variable: p

Cj = a0 +

Âa S

k kj

,

(15.14)

k =1

where Cj is the concentration of variable I during observation j, Skj = zkAPCSkj is the concentration of source k in sample j, and ak is the mean concentration of source k represented by the element.

Chemometrics as a Tool for Treatment Processing of Multiparametric Analytical Data Sets

385

TABLE 15.2 Source-Apportioning Results (in % Contribution) Anthropogenic Factor

Hardness

Biological Factor

Acidic Factor

R2

Cl-

15.8 73.4 81.7 13.7 15.8 73.7 88.1

— — — — 69.6 12.3 —

— 17.7 18.3 71.7 14.6 14.0 11.9

84.2 8.9 — 14.6 — — —

0.39 0.68 0.64 0.66 0.76 0.84 0.58

SO42-

74.2

12.8

—

10.0

0.64

NH 4+

86.7

—

13.3

—

0.67

NO2-

10.1

—

79.9

10.0

0.41

NO 3-

11.0

—

82.4

6.6

0.52

Fe3+

8.8

—

91.2

—

0.44

Ca2+

—

92.4

7.6

—

0.81

Mg2+ Hardness

—

94.2

5.8

—

0.82

—

—

0.81

Variables pH O2 BOD COD DISS N-DISS

—

100

15.2.4.2 Case Study (Struma River) After evaluating the factors responsible for the data structure (the same one used in the PCA case study), an apportioning procedure is carried out to assess the contribution of each possible source to the total mass of the surface water. The modeling was performed according to the apportioning approach of Thurston and Spengler,10 where the total mass of the sample is distributed between the sources identified by PCA (four in this case) after multiple linear regression of the total mass (see Equation 15.13). The apportioning more or less reflects the weight of each latent factor on the sample mass. Thus, it is possible to determine the impact of different factors, both anthropogenic and natural, on surface water quality. Table 15.2 presents the results of source-apportioning for each water quality parameter according to Equation 15.14. It is evident that the contribution of each latent factor to the portion of mass for each chemical parameter varies according to the different impact of the source on the concentration. For instance, the chloride concentration is distributed between the anthropogenic factor (88.1%) and the biological factor (11.9%), but the anthropogenic impact is much higher. Similar conclusions can be drawn for any chemical parameter involved in water quality. The last column of the table shows the multiple correlation coefficient R2. This gives an idea of the suitability of the respective models for each of the chemical parameters. The nonsignificant coefficients are underlined. As a whole, most of the models are statistically appropriate and can be used for predictive purposes.11,12

15.3 CONCLUSIONS The case study presented convincingly illustrates the application of chemometrics as a tool for exploratory data analysis, the aim of which is to extract specific information about river water assessment in a large watershed of national and international significance. A transboundary watercourse, the Struma River flows through Bulgaria and Greece, and the monitoring data should contribute to the mutual understanding of water quality on both sides of the border. The chemometric methods involved (CA, principal components analysis, principal components regression, and

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Analytical Measurements in Aquatic Environments

Kohonen’s SOMs) have made it possible to classify, model, and interpret long-term monitoring data sets and to offer the following significant and practically important conclusions: • Data classification demonstrated the formation of several significant clusters linking different sampling locations with respect to their specific position within the Struma River monitoring network, that is, background sites, rural sites, urban sites, and sites located on the main tributaries; this classification scheme makes it possible to optimize the sampling procedures in the monitoring network; the monitoring can be organized in such a way that a certain number of sites can be neglected, especially when rapid monitoring is needed; each pattern of sites may offer a more limited number of sites for sampling. • The SOM classification takes an additional step toward a better understanding of the links between the sampling sites and introduces greater specificity into the classification scheme; sites with similar levels of pollution can be located on a map in such a way that the distance between the patterns of similar sites becomes obvious and ready for interpretation; additional discriminating parameters can be determined since they are responsible for the formation of the different patterns on the map. • Data projection by principal components analysis have helped to identify hidden factors responsible for the data structure and to interpret these factors accordingly; the sourceapportioning models constructed by a variation of the principal components regression (using the approach of the absolute principal component scores of Thurston and Spengler) reveal a qualitative relationship between identified sources (anthropogenic or natural pollution sources) and the total concentration of each chemical parameter involved in the monitoring procedure. • The classification and the chemometric modeling options have enabled certain information to be obtained on the seasonal patterns of the chemical and physicochemical parameters. • All classification patterns (for both sampling sites or monitoring parameters) as well as the regression models of source apportionment can be further used for problem-solving and correct decision-making on a local or international scale.

ACKNOWLEDGMENT The authors would like to express their sincere gratitude to the National Science Fund, Ministry of Education and Science, Bulgaria, for the financial support to carry out this study [Projects VUH 02/05 (2437) and VUH—203/06 (2472)].

REFERENCES 1. Einax, J.W., H.W. Zwanziger, and S. Geiss. 1997. Chemometrics in Environmental Analysis. Weinheim: VCH. 2. Massart, D.L. and L. Kaufman. 1983. Interpretation of Analytical Chemical Data by the Use of Cluster Analysis. New York: Wiley. 3. Vandeginste, B.G.M., D.L. Massart, L.M.C. Buydens, S. De Jong, P.J. Lewi, and J. Smeyers-Verbeke. 1998. Handbook of Chemometrics and Qualimetrics: Part B. Amsterdam: Elsevier. 4. Simeonov, V. 2001. Classification. Encyclopedia of Environmetrics. New York: Wiley. 5. Bulgarian State Standards. 1985. Water Analysis: Bulgarian Ministry of Environment and Waters. 6. Simeonova, P., V. Simeonov, and G. Andreev. 2003. Water quality study of the Struma River basin, Bulgaria. Centr. Europ. J. Chem. 2: 121–136. 7. Simeonova, P. 2007. Chemometric treatment of missing elements. Ann. Univ. Sof. Fac. Chem. 100: 138–145. 8. Astel, A., S. Tsakovski, P. Barbieri, and V. Simeonov. 2007. Comparison of self-organizing maps classification approach with cluster and principal components analysis for large environmental data sets. Water Res. 41: 4566–4578.

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9. Kohonen, T. 2001. Self-Organizing Maps, 3rd edition. Berlin: Springer. 10. Thurston, G. and J. Spengler. 1985. A quantitative assessment of source contributions to inhalable particulate matter pollution in metropolitan Boston. Atmos. Environ. 19: 9–25. 11. Simeonova, P. 2007. Multivariate statistical assessment of the pollution sources along the stream of Kamchia River, Bulgaria. Ecol. Chem. Eng. 14: 867–874. 12. Simeonova, P., V. Lovchinov, D. Dimitrov, and I. Radulov. 2007. Quality assessment of the Yantra River water monitoring data. Ecol. Chem. Eng. 14: 693–705.

16

Quality Assurance and Quality Control of Analytical Results Ewa Bulska

CONTENTS 16.1 16.2 16.3 16.4

Introduction ...................................................................................................................... General Aspects of QA and QC ....................................................................................... Quality in Chemical Measurements ................................................................................. Assuring the Quality of Analytical Results ...................................................................... 16.4.1 Validation of Analytical Procedure ...................................................................... 16.4.2 Traceability of Analytical Results ........................................................................ 16.5 Monitoring the Quality of Analytical Results .................................................................. 16.5.1 Internal QC ........................................................................................................... 16.5.2 External QC .......................................................................................................... 16.6 Conclusions ....................................................................................................................... Glossary ..................................................................................................................................... References ..................................................................................................................................

389 389 390 391 393 394 394 395 395 396 397 397

If the result of a chemical measurement cannot be trusted, then it has little value and the analysis might as well not have been carried out.

16.1

INTRODUCTION

The quality of chemical measurements, and thus of analytical results, is an important issue in modern society, influencing as it does to a great extent the quality of life as well as global trade. The quality of analytical results is also important in a whole range of scientific disciplines in which chemical measurements are made, for example, biology, geology, medicine, microbiology, mineralogy, ecology, pharmacy, and toxicology. Although it is difficult to evaluate accurately the real impact of chemical measurements on all aspects of economic and social activities, it is clear that they are playing an increasingly important role in decision-making at the official, legal, or private level. It has therefore been recognized by those who need analytical data, and in particular, by those interested in environmentally related investigations, that the quality of the analytical data should be guaranteed. Clearly, it is important to deliver accurate results and to be able to show that they are correct. The importance of quality assurance (QA) and quality control (QC) is therefore well established and accepted in analytical chemistry.

16.2

GENERAL ASPECTS OF QA AND QC

QA is defined as all planned and systematic actions, implemented within a management system and demonstrated as required, that are deemed necessary to engender confidence that a product, process, 389

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or service will fulfill given requirements for quality. In this respect, “Quality” is regarded as the totality of features and characteristics of a product or service (in analytical chemistry this means the results delivered by a laboratory) that bear on its ability to satisfy the stated or implied needs of customers. In the particular case of chemical measurements, this could be expressed as follows: QA covers all the actions undertaken for planning the proper execution of the analytical task in order to obtain accurate and precise measurements.1 The original set of well-defined, strict rules for conducting chemical measurements was developed as the Good Laboratory Practice (GLP) concept by the US Food and Drug Administration (FDA) in the late 1970s and implemented in order to control the quality of analytical results. Later, the US Environmental Protection Agency (EPA) issued similar regulations for the production of agricultural and industrial toxic chemicals. In general, GLP is regarded as the set of conditions under which analytical laboratories should plan, perform, monitor, record, and report their work in such a way that for all samples the history of the results can be traced back. The concepts of quality management (QM) and QA in analytical laboratories were developed primarily to harmonize the world market and in connection with the globalization of the world’s major trading zones; they have now been formally established in relevant directives and standards—formerly ISO 25 and EN 45001, more recently ISO/IEC 17025. The requirements of these standards have become widely accepted as market-regulating tools by both the chemical industry and independent laboratories for routine chemical analysis. At present they are extensively implemented in the form of accreditation, a universally accepted process by which an authoritative body at national or international level gives formal recognition that a laboratory or a person is competent to carry out specific tasks. It is important to point out that the quality of analytical results is not immediate; it can only be achieved if an extensive set of measures are adopted and complied with. Therefore, in parallel to the development of the QA concept, QC systems were introduced as an important tool supporting the QA of chemical measurements. The QC process of examination of laboratory performance in time should always follow QA. QC thus comprises a set of operational techniques and activities used to check whether the requirements for quality are fulfilled. In practice, QC in an analytical chemistry laboratory implies operations carried out daily during the collection, preparation, and analysis of samples, which are designed to ensure that the laboratory can provide accurate and precise results. QC procedures are intended to ensure the quality of results for specific samples or batches of samples and include the analysis of reference materials (RMs), blind samples, blanks, spiked samples, duplicate, and other control samples.2 Although several QA and QC activities are closely related, it should be stressed that QA and QC are not synonymous. QA covers in a broad sense all activities and procedures (managerial and technical) established in the laboratory to assure the overall quality of the delivered results, whereas QC describes the measures used to ensure the quality of individual results or a batch of results. QC is a means of evaluating the current performance of the method being used in the laboratory: it can not only be performed internally in a laboratory (internal QC), but also by external assessment of the results obtained by participation in interlaboratory comparisons (ILCs). The need to carry out both QA and QC in order to achieve the expected quality of analytical results immediately generates the requirement for clearly defined performance criteria. These criteria enable comparability to be achieved via the traceability of analytical results to national or international standards along an unbroken chain of comparisons. Validation is the central task in the development of any analytical method whose capabilities in specific applications can be assessed with the aid of measurement uncertainty. Finally, proficiency testing (PT) serves to demonstrate comparability in terms of the scatter of the results.3

16.3 QUALITY IN CHEMICAL MEASUREMENTS As mentioned before, chemical measurements are essential in different fields, for example, environmental protection, geology, medicine, and biology. Important decisions are often based on these

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measurements, for example, whether environmental compartments are polluted or not, food can be eaten, goods can be sold, a patient should be treated, and also in support of legislation (related to health care and trade), production processes, and social problems. This underscores not only the importance of the chemical measurements themselves, but also the need to guarantee their validity to their users by assuring the quality of the results. The term “users of results” has to be understood in a very broad sense, since it may mean anybody who needs information based on analytical measurements, for example, a client of a testing or research laboratory; a production department; national or local authorities; the judiciary; and customs and excise. To achieve the required quality, the chemist should be involved from the beginning of the process, when the needs of the users of results are defined, until the final report is delivered. In practice, therefore, the analytical chemist has to be consulted at every stage of the process: sample selection, sample storage, and transport procedures, the parameters to be analyzed, and the level of accuracy and precision necessary for an adequate response to be given. This will enable the analyst to set up a scientifically and economically adapted and accepted measurement procedure for the intended purpose as required by the QA system. Moreover, implementation of this system must guarantee that all necessary QC measures can be anticipated, so that the entire quality cycle is under control.4 Nowadays, analytical chemists should be able to demonstrate a sufficient level of expertise to support the end users of the analytical results. This is an important requirement for the proper tailoring of the QA system and QC measures to the intended use of the results. Hence, the laboratory and its staff should be in a position to justify the validity of the delivered results by providing the right answer to the analytical part of the problem; in other words, results have to have demonstrable quality and be fit for a given purpose. Implicit in this is that the measurements carried out are appropriately designed for the given problem.5 Method validation and properly established traceability of results enable analytical chemists to demonstrate this. Then, the QC process designed for particular analytical tasks should concentrate on those parameters that matter most, that is, the ones that have been identified as critical for the given method. Control charts should always be applied, for example, to monitor the stability of the instrument’s calibration and to compare the stability of the values obtained with certified reference materials (CRMs), in both the short term and the long term.

16.4 ASSURING THE QUALITY OF ANALYTICAL RESULTS It is now internationally recognized that for any laboratory to produce reliable data, an appropriate scheme of QA must be implemented. As a minimum, this must ensure that the laboratory is using methods that have been validated as fit for the purpose before their application to a specific task. These methods should be fully documented, staff should be trained, the laboratory infrastructure should be appropriate to the measurements to be made, and mechanisms ensuring that the procedure is under statistical control should be present. Implementation of appropriate QC measures ensures that the data produced and reported are of known quality and uncertainty. Last but not least, the laboratory should participate in PT schemes in order to demonstrate its competence.6 Present-day analytical laboratories are increasingly under pressure to supply objective evidence of their technical competence, of the reliability of their results and performance, and to seek formal certification or accreditation. This pressure may come from the laboratory’s customers (e.g., industry and national bodies) but may also be due to scientific considerations. A QM system in place, validation of methods, uncertainty evaluation, the use of primary standards and CRMs, participation in ILCs, and PT, all serve to assure and demonstrate the quality of measurements. Compared to, say, 30 years ago, the stability of the equipment now available is much improved, and a greater range of RMs for method validation and calibration is accessible. Nevertheless, to achieve mutual (international) acceptance of various bodies of evidence for QA activities, a number of protocols have been developed. The most widely recognized protocols used in chemical measurements and testing are the ISO Guide 9000:2000, ISO/IEC 17025:2005, and OECD Guidelines for GLP, as well as its national and sector equivalents.

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To comply with such requirements, a laboratory has itself to develop a QM system describing its QA activities and the management thereof. Since a quality system and its management often imply a dramatic change in everyday attitudes to laboratory work, sufficient time is needed for awareness building. Time and the relevant training are required to guide a process in which a laboratory is able to build up adequate mechanisms of general QM.7 Implementation of QA rules, together with acceptance of the proper application of metrological principles, are the key issues underpinning the quality of results and is of great importance and benefit to the laboratory. This means acceptance of full traceability and the harmonization of all operations performed. The development of a quality system is and should always be considered a key process toward assuring quality of results. The final step, for example, formal recognition of the quality system by certification or accreditation should be seen as the end-point of this process. A QA system describes the overall measures that a laboratory uses to ensure the quality of its operation. Typical items include suitable equipment, trained and skilled staff, documented and validated methods, calibration requirements, standards and RMs, traceability, internal QC, PT, nonconformance management, internal audits, and statistical analysis. There are a number of QA issues related to the general management systems used within the whole organization: proper supervision of documents and records; in-depth, relevant reviews of contracts with customers; control of nonconforming work; appropriate procedures for carrying out corrective and preventive actions when needed; confidentiality; and competent data handling. In general, QA is that part of the management system within a laboratory responsible for the demanded quality requirements being satisfied. A laboratory should be able to show that its overall organization fulfills the requirements of appropriate standards, which could be ISO 9001:2001 (a general standard that applies to all types of organization) or more specifically, ISO/IEC 17025:2005, which applies to all laboratories carrying out tests and/or calibrations. The QM system should be designed in such a way as to ensure customer satisfaction by meeting customer requirements. This means that the laboratory management should keep a full history of every single sample, from the contract review (agreement between the laboratory and customer on analytical tasks, accuracy, and precision of results, as well as the time and cost of the analysis), through the receipt of the samples to the final report. All samples and related information should be uniquely identified. Moreover, the laboratory should design the process, making sure that any data related to measurements of given item, for example, validation, calibration, QC, and raw data, are identified and retained for a stated period of time. It is also important to demonstrate the competence of the staff performing measurements, which means keeping records of their training and authorization. QA requires a management system to be in place (as described by ISO 9001 and Chapter 4 of ISO/IEC 17025); but the laboratory should also assure quality by fulfilling specific technical requirements. This is well described in Chapter 5 of ISO/IEC 17025, which covers various issues related to accommodation and ambient conditions in the laboratory, validation of the methods used, the need to estimate the uncertainty of measurements, and the need to demonstrate not only the traceability of results by using the proper standards and RMs but also the integrity of the sample. Another important issue as regards QA of results is the laboratory environment. This applies to both the storage of samples, reagents, standards, and RMs and the performance of measurements on particular instruments. In the case of samples, it is important to maintain the integrity of the delivered item: its identity must be safeguarded at all costs; samples must be protected against contamination, destruction, or loss of the compound of interest. Ambient conditions in the laboratory, for example, temperature, humidity, and a particle-free atmosphere, must be controlled and monitored, as they may affect analytical results. Some measurement instruments are sensitive to variations in ambient conditions, so the relevant restrictions should be imposed. In general, the laboratory should have a certificate for all the volumetric glassware and standards. Moreover, all measurement instruments should be appropriate to their intended uses; they should be calibrated and maintained in good order to ensure accuracy of measurements. All these procedures should be documented.

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With an appropriate QA system in place, a laboratory is in a position to assure customers that it has adequate facilities and equipment for carrying out particular measurements. Moreover, the laboratory should be able to demonstrate that analyses are performed by competent and authorized staff according to well-described procedures and validated methods. Well-designed and properly implemented QA supports a laboratory to ensure that the delivered results are valid and fit for a stated purpose. It is therefore clear that a laboratory must take appropriate QA measures to ensure that it is capable of providing data of the required quality and that it actually does so. Method validation is therefore an absolutely essential component of the measures that a laboratory should introduce in order for it to produce reliable analytical data.

16.4.1

VALIDATION OF ANALYTICAL PROCEDURE

Validation of the analytical procedure is regarded as one of the most important issues of QA. Before selecting the measurement procedure (analytical method) for a particular purpose, the laboratory should consider its experience, the technical infrastructure at its disposal, and the expected time frame and financial outlay. Validation of the analytical procedure provides necessary information on its performance characteristics and raises the confidence of users in the results.8 According to ISO/IEC 17025, validation is confirmation by the examination and provision of objective evidence that the particular requirements for a specific intended use are fulfilled. Performance parameters can be divided into two groups. The first group refers to the properties of the measurement procedure: detection limit and determination limit, working range, linearity, and sensitivity. The second group covers the properties of the results obtained with this particular measurement procedure, that is, traceability and uncertainty (including recovery, robustness, precision, and accuracy).9 Full validation of an analytical method usually comprises an examination of its characteristics in interlaboratory method performance studies. However, before a method is subjected to validation by collaborative studies, the method must be validated by a single laboratory, usually by the laboratory that developed or modified this particular measurement procedure. Method validation can be described as the set of tests used to establish and document the performance characteristics of a method and against which it may be judged, thereby demonstrating that the method is fit for a particular analytical purpose. There are two approaches to single-laboratory method validation: The traditional one that identifies and then evaluates the set of analytical parameters, and a more recent one that is based on the evaluation of uncertainty. The newer approach places strong emphasis on measurement uncertainty being evaluated using a “component-by-component” approach: the variance or uncertainties inherent in an analytical method are identified and quantified as input quantities. These input quantities are then combined to give an estimate of the overall uncertainty of the analytical procedure. This approach can be regarded as a development of the traditional approach but with several components of overall uncertainties being identified and quantified together. Validation should cover the whole analytical procedure—from the preparation of the laboratory sample to the evaluation of the result, that is, the whole range of intended matrices, and should be performed within the expected range of concentrations. The intended use of the analytical results should also be considered. This means that the result can be used to evaluate compliance with regulations, to maintain quality and process control, to make regulatory decisions, to support national and international trade, and, last but not least, to support research. It should be clearly understood that validation is carried out in order to evaluate the performance of the applied analytical procedure, not the performance of the analyst or the laboratory. Several techniques can be used for validation, the most highly recommended ones being (i) evaluation of uncertainty (i.e., a systematic assessment of the quantities influencing the result); (ii) performing CRM analysis; (iii) participation in ILCs/PTs; and (iv) comparison of results with other analytical

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methods. When a fully validated method is available, the analyst can envisage starting a statistical control system (QC), including the follow-up of performance with the aid of control charts. If the laboratory develops the validation method in-house, there always needs to be some sample to be used for this purpose; a sample that best mimics routine samples is the most suitable. The usual practice is that a routine sample is used for this purpose as knowledge of the true value is not a critical issue at this stage. Next, the trueness of a method is usually determined by analyzing an appropriate CRM and/or participating in an ILC, one with an externally defined reference value.10

16.4.2

TRACEABILITY OF ANALYTICAL RESULTS

Worldwide acceptance of analytical results requires reliable, traceable, and comparable measurements. A key property of a reliable result is its traceability to a stated reference. Traceability basically means that a laboratory knows what is being measured and how accurately it is measured. It is also an important parameter where comparability of results is concerned and is usually achieved by linking the individual result of chemical measurements to a commonly accepted reference or standard. The result can therefore be compared through its relation to that reference or standard. Every link in the traceability chain must be based on the comparison of an unknown value with a known value. The stated reference might be an International System of unit (SI) or a conventional reference scale such as the pH scale, the delta scale for isotopic measurements, or the octane number scale for petroleum fuel. In order to be able to state the uncertainty of the measurement result, the uncertainty of the value assigned to that standard must be known. Therefore a traceability chain should be designed and then demonstrated using the value of the respective standard with its uncertainty.11 As already mentioned, the analytical parameters required for method validation and for the estimation of measurement uncertainty can be evaluated without assigned values. But to assess the accuracy of delivered results, as stated in ISO/IEC 17025, there is a requirement for assigned values with a stated uncertainty, which are traceable to the same reference as the analytical results of the method used. In physics, measurements are made in accordance with the SI units, which were introduced under the convention of the meter. In chemical measurements, traceability of results to SI units is not always possible. Therefore, the role of chemical standards is decisive in establishing the comparability of results between laboratories. During the validation of the analytical procedure, traceability of the result can be demonstrated by comparison against the certified value of a CRM, which provides exactly this traceable assigned value with a stated uncertainty.

16.5 MONITORING THE QUALITY OF ANALYTICAL RESULTS In analytical laboratories that are expected to deliver results with a defined level of accuracy and uncertainty, QC basically involves examining at regular intervals whether the QA system was well designed and executed in such a way as to fulfill the requirements over time. In practice, in accordance with ISO/IEC 17025, the laboratory undertakes QC procedures for monitoring the validity of a test. The resulting data are recorded in such a way that trends are detectable and, where practicable, statistical techniques are applied to the reviewing of the results.12 This monitoring is planned with respect to the frequency of performing QC measurements and reviewed in order to assure quality over time. Monitoring of the QC process should include the regular use of CRMs or RMs and replicate tests for internal QC, as well as participation in ILC schemes for external quality assessment. Clearly, QC activities are an essential element of a QA system. Moreover, all these activities should be planned and well documented, and QC data should be analyzed so that corrective action can be taken whenever needed. QC activities mean comparisons of results and their uncertainties with quality criteria and/or reference data, and typically are done by – The use of control charts of the results obtained for RMs, CRMs, in-house control samples, blanks, and so on

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– Regular checks of instrument performance by calibration or adjustments – Checks on the purity and stability of reagents and solutions used – Monitoring the ambient conditions in the whole laboratory or in part of it, whenever this is relevant to the measurements performed – Examination of the repeat results obtained by the same procedure on the same sample in order to examine the influence of any factors on the results

16.5.1

INTERNAL QC

Internal QC involves a continuous evaluation of the selected measures on the basis of various kinds of data. The usual way of performing QC is to use control samples, which should be applied throughout the analytical process, starting with the sample entering the laboratory and ending with the measurement report. The best practice is to analyze control samples in parallel to the routine samples in the same way. The results obtained for the control samples should be plotted on a control chart to show that the results lie within given limits. If the result falls outside the limits, no analytical results are reported and corrective action has to be taken. It is commonly accepted that for QC purposes various kinds of RMs can be used as control samples. It should be stressed that the term “reference material” is of a generic nature and describes any material, sufficiently homogenous and stable with respect to one or more specific properties, which has been established as being fit for its intended use in a measurement process. RMs can be used for calibrating a measurement system, assessing a measurement procedure, assigning values to other materials, and for QC. Even so, a single RM cannot be used in the same measurements for two different purposes. It can only be used for a single purpose in a given measurement at any one time, for example, either for calibration of instruments or for QC. With the use of in-house RMs for method validation, calibration and QC are common practices in environmental laboratories. CRMs are a special kind of RMs—they are materials possessing special characteristics—a certificate, and traceable, assigned values with an uncertainty statement. The typical way of examining QC data is to use various kinds of control charts, on which results are plotted versus time. Control charts have been developed for monitoring production as a means of statistical process control (SPC). Control charts have also been adopted for analysis as statistical quality control (SQC), where they serve as a warning sign for the laboratory. Quality is no longer guaranteed whenever a measurement exceeds the alarm limit. At regular intervals, the analyst determines the substance to be monitored in the control material and reports the result graphically. When starting a chart, the analyst has to determine from several replicate measurements the mean value, as well as the standard deviation, that represents the reproducibility of the method. This reproducibility value will allow acceptance limits to be predefined, for example, “warning” and “alarm” levels, expressed as 2 or 3 times the standard deviation, respectively. Apart from the standard Shewart charts, the analyst can also apply X-charts, on which the mean of several replicate measurements is plotted, or R-charts, where the difference between two replicate measurements is plotted. X- and R-charts give an indication of the reproducibility of the method. Drift in analytical procedure, for example, slows changes in the system caused by the aging of parts of instruments, decalibration in wavelength, or the aging of calibration stock solutions, can be detected early when a Cusum chart (cumulative sum) is applied. In Cusum charts, the analyst reports the cumulative sum of the differences between delivered and reference values. If this reference value is certified (CRM), the Cusum chart allows the accuracy of the determination to be monitored.

16.5.2

EXTERNAL QC

All the above discussion was focused on various activities performed within the laboratory, referred to as internal QC; but it is also extremely important for a laboratory to obtain an independent assessment of its performance. This can be achieved by participation in ILC schemes such as PT or

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collaborative studies. Laboratories participating in an ILC carry out chemical measurements using their routine analytical procedures on the ILC test sample with an undisclosed assigned value. Participation in external quality assessment schemes provides an external measure of the laboratory’s performance by comparison with other laboratories carrying out similar types of analysis. The main objective of this external assessment is to obtain an indication of laboratory performance on the basis of a number of commonly accepted scores. In general, all scores involve the difference between a laboratory’s result and the assigned value, which is determined by the target range, for example, the standard deviation or uncertainty of the assigned value. One important task of the organizers of any ILC is to carry out a statistical evaluation of participants’ results, as laid down by the ISO 13528:2005 standard. At fi rst, a clear statement should be given on how the assigned value was delivered: by formulation, as a consensus value, or by CRMs being used for the particular ILC. Although CRMs are seldom used as ILC samples, their advantage is that the assigned value can be used for ensuring the traceability of the results in the laboratory. The range (denominator) used for scoring can be defined as the target range or calculated standard deviation of all data. The drawback of the latter is that it may not reflect the reproducibility of the analytical method being assessed. The evaluation of laboratory results usually applied is the z-score, where the difference is related to the target range. When the z-score is below 2, the result is considered satisfactory; when the z-score lies between 2 and 3, the result is considered questionable; and a z-score above 3 indicates an unsatisfactory performance by the laboratory. Another type of scoring, known as the zeta-score, takes into account the standard uncertainty of the assigned value and the uncertainty of the laboratory result. This approach requires that the laboratory should provide a valid estimate of its uncertainty. The zeta-score can be interpreted using the same criterion as the z-score. A third type of scoring, which takes into account the expanded uncertainties of the assigned value and the laboratory’s result, is the En number. When the coverage factor of expanded uncertainty is equal to 2, the En score below 1 indicates that the result is satisfactory. An important aspect of external QC performed via ILC participation is that the laboratory is assured of the confidentiality of its identity and that of the other participating laboratories. The laboratory is identified only by a code number, which is shown in the report. It is recommended that laboratories take part in a number of ILCs; in this way, they will be able to monitor their performance over time, evaluate trends, and take corrective action when needed.

16.6

CONCLUSIONS

Modern society depends on the skills of analytical chemists to reliably measure the concentrations of compounds of interest. Apart from posing a risk to our health and the environment, an incorrect measurement is a waste of time and money. The processes of QA and QC have therefore been established as tools for ensuring the reliability of results delivered by laboratories to their customers. QA describes the overall measures that a laboratory uses to ensure the quality of its operations. In practice, QA covers a set of managerial and technical procedures implemented in a laboratory, supported by interacting working systems that include QC. QC covers all the operational techniques and activities for monitoring the overall performance of a given laboratory against stated requirements for quality. QC procedures are intended to ensure the quality of results delivered for specific samples or batches of samples. They include the analysis of RMs and/or measurement standards; analysis of blind samples, blanks, spiked, or duplicate samples; the use of QC samples and control charts; and participation in ILCs. To conclude, the use of RMs and the regular participation in ILC schemes have become fundamental pillars of the assurance and control of analytical data quality in terms of precision and accuracy, thus proving the competence of analytical laboratories.

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GLOSSARY Accuracy: The closeness of agreement between a test result and the accepted reference value. Interlaboratory comparison (ILC): The organization, performance, and evaluation of tests on the same sample by two or more laboratories in accordance with predetermined conditions to determine testing performance. According to purpose, they can be classified as collaborative studies or proficiency studies. Performance characteristic: A functional quality that can be attributed to an analytical method, for example, specificity, accuracy, trueness, precision, repeatability, reproducibility, recovery, detection capability, and ruggedness. Performance criteria: Requirements for a performance characteristic according to which it can be judged that the analytical method is fit for the intended use and generates reliable results.

REFERENCES 1. Neidhart, B. and W. Wegscheider (eds). 2001. Quality in Chemical Measurements. Berlin: Springer. 2. Kellner, R., J.M. Mermet, M. Otto, and H.M. Widmer (eds). 1998. Analytical Chemistry. Weinheim: Wiley-VCH. 3. Otto, M. 1999. Chemometrics: Statistical and Computer Application in Analytical Chemistry. Weinheim: Wiley-VCH. 4. Robouch, P., E. Bulska, S. Duta, M. Lauwaars, I. Leito, N. Majcen, J. Norgaard, M. Suchanek, E. Vassileva, and P. Taylor. 2003. TrainMiC—Training in Metrology in Chemistry. Luxemburg: European Communities. EUR Report 20841 EN. 5. ISO/IEC 17025. 2005. General requirements for the competence of testing and calibration laboratories, ISO, Geneva. 6. ISO 5725 Part 1–6. 1998. Accuracy (trueness and precision) of measurement methods and results, ISO, Geneva. 7. ISO/IEC Guide 99. 2007. International vocabulary of metrology—basic and general concepts and associated terms (VIM), ISO, Geneva. 8. Eurachem/CITAC Guide. 1998. Quality assurance for research and development and non-routine analysis. 9. Eurachem/CITAC Guide. 1998. A fitness for purpose of analytical measurements: A laboratory guide to method validation and related topics. 10. Bulska, E. and P. Taylor. 2003. Do we need education in metrology in chemistry? Anal. Bioanal. Chem. 377: 588–589. 11. King, B. 2000. The practical realization of the traceability of chemical measurements standards. Accred. Qual. Assur. 5: 429–436. 12. Prichard, E. and V. Barwick. 2007. Quality Assurance in Analytical Chemistry. Chichester, Hoboken, NJ: Wiley.

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Analytical Procedures for Measuring Precipitation Quality Used within the EMEP Monitoring Program Wenche Aas

CONTENTS 17.1 Scope of the Rural Monitoring Network in Europe ......................................................... 17.2 Analytical Methods Used for Precipitation Samples in Rural Areas in Europe .................................................................................................. 17.2.1 Collection of Precipitation .................................................................................... 17.2.2 Measurements of the Main Ions, pH, and Conductivity in Precipitation ............. 17.2.2.1 Introduction ............................................................................................ 17.2.2.2 Determination of pH in Precipitation .................................................... 17.2.2.3 Determination of Conductivity .............................................................. 17.2.2.4 Ion Chromatography .............................................................................. 17.2.2.5 Spectrophotometry ................................................................................. 17.2.2.6 Determination by Flame Atomic Spectroscopy .................................... 17.2.3 Measurement of Heavy Metals and Metalloids in Precipitation .......................... 17.2.3.1 Introduction ............................................................................................ 17.2.3.2 Sample Preparation ................................................................................ 17.2.3.3 Inductively Coupled Plasma Mass Spectrometry .................................. 17.2.3.4 Graphite Furnace Atomic Absorption Spectroscopy ............................. 17.2.3.5 Flame-Atomic Absorption Spectroscopy .............................................. 17.2.3.6 Cold Vapor Atomic Fluorescence Spectroscopy ................................... 17.2.4 Measurements of POPs in Precipitation Using GC-MS ....................................... 17.3 Data Quality Control ........................................................................................................ 17.4 Future Perspectives ........................................................................................................... Acknowledgments ...................................................................................................................... References ..................................................................................................................................

17.1

399 401 401 402 402 403 403 404 404 405 405 405 405 406 407 408 408 408 409 410 411 411

SCOPE OF THE RURAL MONITORING NETWORK IN EUROPE

The “Cooperative program for monitoring and evaluation of long-range transmission of air pollutants in Europe” (EMEP) was launched in 1977 as a response to the growing concern over the environmental effects of acid deposition. EMEP was organized under the auspices of the United 399

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(b)

>0.5 0.3–0.5 0.1–0.3 <0.1

>0.5 0.3–0.5 0.1–0.3 <0.1

(c)

>0.5 0.3–0.5 0.1–0.3 <0.1

FIGURE 17.1 Annual volume-weighted concentration of (a) ssc SO 42-, (b) NO3-, and (c) NH4+ in precipitation in EMEP 2006, units mg S or N/L.1

Nations Economic Commission for Europe (ECE). Today, EMEP is an integral component of the cooperation under the Convention on Long-range Transboundary Air Pollution (CLTRAP) launched in 1979. Including EMEP, there are eight protocols under the Convention that identify specific measures to be taken by Parties to cut their emissions of air pollutants. The main objective of EMEP is to provide governments with information on the deposition and concentrations of air pollutants, as well as on the quantity and significance of the long-range transmission of pollutants and transboundary fluxes. Monitoring of atmospheric concentrations and deposition is one of the basic ways of achieving the objectives of EMEP. In addition to measurements, the program includes official reporting of national emissions, the development of atmospheric dispersion models, and integrated assessment. The EMEP measurements are important for model validation and compliance monitoring. In other words, it is necessary to have measurements that are robust and useful for trend analysis, which is needed to see whether the reductions in emissions defined under the different protocols are also observed in the deposition. The monitoring requirements provide important data for the assessment of environmental issues also considered by other conventions, including local air quality, climate change, water quality, and biodiversity. Of the different regional monitoring networks in the world, EMEP is the one with the longest time series; it is also one of the largest. The different monitoring networks have harmonized their methods as far as possible to avoid duplication and noncomparable measurements. The methods and procedures described in this chapter are generally derived from the development and experience gained within EMEP, as well as information provided by similar programs in North America, by the World Meteorological Organization/Global Atmospheric Watch (WMO/GAW), and various other research programs. The EMEP monitoring network of precipitation chemistry consists of about a hundred stations distributed in almost 30 countries across Europe.1 All of these measure inorganic ions as well as pH and conductivity. Figure 17.1 illustrates the concentration levels of sulfate (corrected for sea salt), nitrate, and ammonium in 2006. The monitoring sites of heavy metals and persistent organic pollutants (POPs) are less densely distributed;2 in 2006, there were around 50 for heavy metals such as lead

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(b)

>3 2–3 1–2 <1

>10 8–10 6–8 <6

FIGURE 17.2 Annual volume-weighted concentration of (a) Pb (in mg/L) and (b) Hg (in ng/L) in precipitation in EMEP 2006.2

and cadmium, 13 for measuring mercury, and 10 for POPs (Figure 17.2). In addition to precipitation chemistry, the EMEP program covers air measurements of major ions, photo-oxidants, particulate matter, POPs, and heavy metals.3

17.2 ANALYTICAL METHODS USED FOR PRECIPITATION SAMPLES IN RURAL AREAS IN EUROPE For the majority of the methods, the necessary quality assurance is provided by a combination of simple and robust sampling techniques with well-described sampling equipment, and the use of synthetic control samples for the chemical analyses. The methods defined in EMEP 4 are harmonized whenever possible with recommendations in other networks such as WMO/GAW 5 and standardization organizations such as the European Committee for Standardization (CEN).

17.2.1

COLLECTION OF PRECIPITATION

The purpose of the sampling and chemical analysis of precipitation in the EMEP network is generally to obtain an accurate indication of the chemical composition of precipitation, which can be used to derive wet deposition estimates on both a short-term (day–month) and a long-term basis. Precipitation is collected in a vessel with a horizontal opening of defined dimensions. The sampling equipment consists of in principle a funnel and a receiving vessel. In order for the sample not to be contaminated from the ground during heavy rain, the rim of the funnel should be positioned 1.5–2 m above the ground level. It is recommended that the sampler be further protected from the settlement of dust and the adsorption of gases during dry periods by an automatic lid, which opens after activation of a precipitation sensor—a wet-only collector. Bulk samplers are recommended only if it can be shown that contamination by the dry deposition of dust and gases, for example, ammonia, is negligible. The collecting vessel must be constructed from a material that does not alter the chemical composition of the sample. Polyethylene, tetrafluoroethylene, and tetrafluoroethylene-fluorinated ethylpropylene copolymer are generally recommended. Glass and metal containers are not good for measuring the major ions and must be avoided, as these materials are liable to produce both positive and negative artifacts for cations. The sample should give a reliable measure of the amount of precipitation on a daily basis. It is recommended to equip sites with a rain gauge in addition to the wet-only collector. Collecting a representative sample of snow for precipitation chemistry measurements poses special problems. Most electronic sensors on precipitation chemistry samplers do not detect snow, particularly light, dry snow, as efficiently as rain. Light, dry snow may also fall into and then be blown out of an open container or funnel. Snow may stick to sampler parts and later be blown into the sample container. Ice may coat sampler parts and prevent proper operation. Heavy snow may

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Analytical Measurements in Aquatic Environments

even fill the container to overflowing and block sampler operation. Some samplers are specially adapted to improve snow collection. Heating the collector lid and other moving parts to about 4–5ºC may help prevent snow and ice buildup from interfering with sample collection or sampler operation. For samplers with funnels, applying enough heat to melt snow and ice may be necessary, if the funnel depth is too shallow to accommodate the entire volume. Care should be taken when applying heat to avoid increased sample loss due to evaporation or sublimation. One way to avoid having to heat the sample is to use an open container instead of a funnel.5 For the inorganic ions in precipitation, the precipitation volume of the daily (or weekly) samples is measured either by weight or by volume, after which an aliquot is transferred to a sample storage and transport bottle. To a large extent, the sampling of heavy metals follows the same procedures as for the main components in the precipitation, but because of the sensitivity of heavy metal samples to contamination, extra precautions need to be taken. The precipitation volume in mm is calculated from the weight of the water and its density, and the sampler is shipped to the laboratory without transferring any sample to smaller transport bottles. Mercury is collected in special precipitation samplers. Two alternative materials may be used for funnels and collection bottles: borosilicate glass and a halocarbon such as Teflon or PFA. Borosilicate glass is often preferred because of its lower cost and general availability. Quartz glass can also be used but is generally avoided owing to its high cost. For extended sampling periods, diffusion of Hg0 into the precipitation sample collected has to be prevented, since it could contribute to the mercury content of the sample via oxidation to water-soluble forms. This is easily done by inserting a capillary tube between the funnel and the bottle. The sample bottles also have to be shielded from light to avoid photo-induced reduction of the mercury in the precipitation sample.6,7 Regardless of the duration of the sampling period, there is always the possibility of chemical degradation of the sample in the field during the course of sample collection, during shipment from the field to the laboratory, and prior to analysis at the laboratory. The sample preservation practices followed by most networks often do not completely prevent chemical degradation. One recommended practice is to store samples at <4°C in the laboratory before analysis. Alternatively, chemical biocides can be added to the samples to prevent degradation. But this requires strict quality control procedures to ensure that these additives contain nothing that will contaminate the samples. To date, biocides have been used primarily for research purposes and only on a limited basis.5

17.2.2 MEASUREMENTS OF THE MAIN IONS, PH, AND CONDUCTIVITY IN PRECIPITATION 17.2.2.1 Introduction In connection with the determination of transboundary fluxes and deposition of air pollutants, the concentrations of sulfate, ammonium, and nitrate in precipitation are particularly important. However, determination of one or more sea-salt constituents (Na, Cl, and Mg) is also necessary in order to determine the fraction of the sulfate concentration due to marine sea-spray aerosols. Moreover, determination of the base cations Ca, K, and Mg is desirable in order to obtain an indication of the large-scale deposition of bases; this is needed in connection with the determination of critical loads. Finally, pH and conductivity should be determined in order to obtain some idea of the overall composition of the samples, and to check the consistency of the chemical analyses. Most of the major ions in precipitation samples can be determined by ion chromatography, which is the generally recommended method for anions such as chloride, nitrate, and sulfate, although other methods may be used for some compounds. Table 17.1 gives a list of alternative recommended methods. These last three anions are not part of the standard EMEP measurement program. They are included here, however, because they are found in precipitation samples in concentrations comparable to those of some of the other ions, and may be necessary to explain the ion balance and measured conductivities, particularly for samples with pH > 5. In other parts of the world, for example, the tropics, organic acids may be of great importance and should be included.5

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Analytical Procedures for Measuring Precipitation Quality

TABLE 17.1 Recommended Methods for Chemical Analysis of Main Ions in Precipitation Component or Parameter

Recommended Methods

Conductivity

Conductivity cell and resistance bridge

Hydrogen ion (H+)

Potentiometry (glass electrode) pH < 5.0 Ion chromatography

Alternative Titration

Sodium ion (Na+)

Atomic absorption spectroscopy (AAS)

Spectrophotometry (indophenol blue color reaction) Ion chromatography

Potassium ion (K+)

AAS

Ion chromatography

Magnesium ion (Mg2+)

AAS

Ion chromatography

Calcium (Ca2+)

AAS

Ion chromatography

Ammonium ion (NH+4)

Sulfate ion (SO42-)

Ion chromatography

Nitrate ion (NO 3-)

Ion chromatography

Chloride ion (Cl-)

Ion chromatography

Spectrophotometry, Griess method (reduction to nitrite and diazotation) Spectrophotometry [displacement of SCN- in Hg(SCN)24 , determination of colored Fe(SCN) complex]

Bicarbonate ion (HCO3-)

Titration

Formate ion (HCOO-)

Ion exclusion chromatography

Ion chromatography

Acetate ion (CH3COO-)

Ion exclusion chromatography

Ion chromatography

Note that most of the components can be determined by ion chromatography, which is strongly recommended for sulfate, nitrate, and chloride anions. However, ion chromatography holds no advantages over conventional methods when it comes to the determination of ammonia and base cations. 17.2.2.2 Determination of pH in Precipitation The method is based on determining the potential difference between an electrode pair, consisting of a glass electrode sensitive to the difference in the hydrogen ion activity in the sample solution and the internal filling solution, and a reference electrode, which is supposed to have a constant potential independent of the immersing solution. The pH of precipitation varies between about 3.0 and 7.5. Past experience from regional networks and laboratory intercomparisons has shown that measuring pH in precipitation is difficult, mainly because of the low ionic strength of the samples.5 Samples may also degrade as a result of biological activity and should therefore be kept refrigerated until the time of analysis, when they are brought to room temperature. The pH measurements should be carried out within 2 days of a sample’s arrival at the laboratory. It is strongly recommended that the electrode system be checked at regular intervals by comparison of the “apparent pH” of a low-ionic-strength solution with a known pH or hydrogen ion concentration. The pH readings should be within 0.02 or 0.05 pH units of the “theoretical” result. The pH meter should have both an intercept and a slope adjustment and should be capable of measuring to within ±0.01 pH unit. 17.2.2.3 Determination of Conductivity Conductance is the inverse of resistance in a solution and conductivity is the inverse of specific resistance. Conductivity is measured with a bridge and a measuring cell; it is dependent on the distance between the electrodes and their area in the measurement cell. The conductivity of precipitation samples depends on the concentrations of various ion species and their different abilities to transport electric charges in solution, that is, the equivalent conductivity of the

404

Analytical Measurements in Aquatic Environments

ion species. By comparison with estimated conductivity and in combination with ion balance calculations, conductivity measurements can help identify ion concentrations that are wrong or inaccurate. 17.2.2.4 Ion Chromatography Basic information about ion chromatography will be found in Weiss.8 The ISO norm 10304-19 sets out the details of the ion chromatographic determination of anions in solution in lightly contaminated waters. A small volume of the sample, typically <0.5 mL, is introduced into the injection system of an ion chromatograph. The sample is mixed with an eluent and pumped through a guard column, a separation column, a suppressor device, and a detector, normally a conductivity cell. The separation column is an ion exchange column that has the ability to separate the ions of interest. The separation column is often preceded by a shorter guard column containing the same substrate as the separation column in order to prevent the separation column from becoming overloaded and/or blocked by particles. Different types of separation columns, eluents, and suppression devices have to be used for anions and cations. Each ion is identified by its retention time within the separation column. Any species with a retention time similar to that of the main ions can interfere. Large amounts of one of the ions may interfere by reducing the peak resolution of the next ion in the elution sequence. Sample dilution may then be necessary. In some systems the so-called negative water dip at the start of the chromatogram may interfere with the Cl- determination. This can be avoided by adding a small amount of concentrated eluent to all samples and calibration standards to match the eluent concentration. The ion chromatograph is calibrated with standard solutions containing known concentrations of the target ions. Calibration curves are constructed from which the concentration of each ion in the unknown sample is determined. It is strongly recommended to match the calibration solutions with the sample matrix. Five calibration solutions and one zero standard (blank, normally water) are needed to generate a suitable calibration curve. The range to be used will depend on the concentration range for the different samples. All reagents must be of recognized analytical grade. The water used for dilution should be deionized and filtered. The water should have a resistance of >10 MW/cm and not contain particles >0.20 μm. The bottles that are to contain sample, calibration standards, and reagent solutions should be made of polyethylene or polypropylene. For the anions, borosilicate glass may also be used. Stock standard solutions may be purchased as certified solutions from different manufacturers or NIST (National Institute for Standards and Technology, USA), or else prepared from salts or oxide that are dried, dissolved, and diluted. 17.2.2.5 Spectrophotometry Nitrate, ammonium, and chloride may be determined spectrophotometrically if an ion chromatograph is not available. 17.2.2.5.1 Griess Method for Nitrate This method can be used to determine the nitrate content in precipitation within the range from 0.02 to 0.23 mg NO3–N/L (0.1–1.0 mg NO3/L). Nitrate is reduced to nitrite using cadmium treated with copper sulfate as reducing agent in the presence of ammonium chloride. With this method the sum of nitrate and nitrite is determined. Nitrite and sulfanilamide form a diazo compound that couples with N-(1-naphthyl)ethylenediamine dihydrochloride to form a red azo dye. The concentration in the solution is determined spectrophotometrically at 520 nm. Note that nitrite will interfere with the determination of nitrate. 17.2.2.5.2 Indophenol Blue Method for Ammonium This method is applicable to the determination of the ammonium content in precipitation within the 0.04–2.0 mg NH4/L range. In alkaline solution (pH 10.4–11.5), ammonium ions react with hypochlorite to form monochloramine. In the presence of phenol and excess hypochlorite, the monochloramine

Analytical Procedures for Measuring Precipitation Quality

405

will form a blue-colored compound, indophenol, when nitroprusside is used as catalyst. The concentration of ammonium is determined spectrophotometrically at 630 nm. 17.2.2.5.3 Mercury Thiocyanate-Iron Method for Chloride The method can be used for the direct determination of the chloride ion content in precipitation samples within the 0.05–5 mg/L range. Chloride ions will replace the thiocyanate ions in undissociated mercury thiocyanate. The thiocyanate ions thus released react with ferric ions to form a dark red iron–thiocyanate complex. 17.2.2.6 Determination by Flame Atomic Spectroscopy Sodium, potassium, magnesium, and calcium in precipitation can be analyzed by atomic spectroscopic methods or by ion chromatography. Both flame- (AAS and AES) and plasma (ICP-AES and inductively coupled plasma mass spectrometry, ICP-MS)-based methods can be used. For these ions, ion chromatography has no special advantage concerning sensitivity, precision, and accuracy over the spectroscopic methods, but analysis of all the ions in one run is not possible with flame AAS or AES. The method can normally be used to determine sodium, magnesium, potassium, and calcium in precipitation within the 0.01–2 mg/L range, but this will depend to a certain degree on the commercial instruments used. The ions in the sample solution are converted to neutral atoms in an air–acetylene flame. Light from a hollow cathode or an electrodeless discharge lamp (EDL) is passed through the flame. The light absorption of the atoms in the flame, which is proportional to the ion concentration in the sample, is measured by a detector following a monochromator set at the appropriate wavelength. This principle holds for measurements performed in the AAS mode. In the AES mode, the light emitted from the atoms excited in the flame is measured. Most commercial instruments can be run in both modes. Sodium may be measured more favorably in the emission mode. In atomic absorption spectroscopy (AAS) both ionization and chemical interferences may occur. These interferences are caused by other ions in the sample and result in a reduction of the number of neutral atoms in the flame. Ionization interference is avoided by adding a relatively high amount of an easily ionized element to the samples and calibration solutions. For the determination of sodium and potassium, cesium is added. To eliminate chemical interferences from, for example, aluminum and phosphate, lanthanum can be added to the samples and calibration solutions. EDL or hollow cathode lamps are used to determine Na, K, Mg, and Ca. Single-element lamps are preferred, but multielement lamps may be used. EDLs are more intense than hollow cathode lamps, and are preferred for K and Na. When performing analyses in emission mode, no lamps are needed.

17.2.3

MEASUREMENT OF HEAVY METALS AND METALLOIDS IN PRECIPITATION

17.2.3.1 Introduction In EMEP, ICP-MS is defined as the reference technique. The exception is mercury, where cold vapor atomic fluorescence spectroscopy (CV-AFS) is chosen. Other techniques may be used, if they are shown to yield results of a quality equivalent to that obtainable with the recommended method. These other methods include graphite furnace atomic absorption spectroscopy (GF-AAS), flameatomic absorption spectroscopy (F-AAS), and CV-AFS. The choice of technique depends on the detection limits desired. ICP-MS has the lowest detection limit for most elements and is therefore suitable for remote areas. The techniques described in this manual are presented with minimum detection limits. Table 17.2 lists the detection limits for the different methods. 17.2.3.2 Sample Preparation After measuring the sampling volume by weighing the storage bottles, nitric acid should be added (this can also be added before sampling)—1 mL of supra-pure conc. HNO3 per 100 mL of precipitation. This will dissolve the metals that could be adsorbed on the walls of the container and will also

406

Analytical Measurements in Aquatic Environments

TABLE 17.2 Minimum Detection Limit for Different Analytical Methods Element

ICP-MS10 (ng/mL)

GF-AAS11 (ng/mL)

F-AAS12 (ng/mL)

As

<0.01

0.056

0.02

Cd

<0.01

0.0014

0.5

Cr

<0.01

0.0038

2

Cu

<0.01

0.015

1

Ni

<0.03

0.072

2

Pb

<0.001

0.007

10

Zn

<0.02

0.006

0.8

0.2

0.001

Hg

prevent the growth of microorganisms. Samples for the analysis of total mercury should be preserved with low blank HCl (5 mL 30% acid/L). The precipitation sample may contain a large fraction of undisclosed material. Such nonhomogenous samples should be filtered before analysis to avoid problems with the analytical instrument. Filtration also ensures that the precipitation sample is homogenous, which makes the analysis more reproducible. Either a disposable syringe filter or vacuum filtration equipment should be used to filter the acidified samples. As it is easy to contaminate samples for heavy metal analysis, they must be handled with care; gloves must always be worn. 17.2.3.3 Inductively Coupled Plasma Mass Spectrometry ICP-MS is a multielement technique that is suitable for trace analysis; it offers a long linear range and low background for most elements. ICP-MS is a technique where the ions produced in inductively coupled plasma are separated in a mass analyzer and detected. The sample solution is fed into a nebulizer by a peristaltic pump. The nebulizer converts the liquid sample into a fine aerosol that is transported into the plasma by an Ar gas flow. In the plasma the sample is evaporated, dissociated, atomized, and ionized to varying extents. The positive ions and molecular ions produced are extracted into the mass analyzer. Detailed descriptions of the ICP-MS technique can be found in a number of textbooks.13,14 In ICP-MS analysis it is necessary to consider interferences such as isobar overlap and physical interference (Table 17.3). Isobar overlap exists when two elements have isotopes of essentially the same mass. Isobar overlap may also occur as a result of the formation of polyatomic species consisting of two or more atomic species, for example, ArO+. They are formed by rapid ion–molecule reactions between the components of the solvent or sample matrix and the constituents of the plasma. The dominant species in the plasma and its surroundings are Ar, O, N, and H. These elements can combine with each other to give a variety of polyatomic ions. The extent to which polyatomic ions form depends on several parameters, including sampling geometry, plasma and nebulizer conditions, choice of acids and solvents, and the nature of the sample matrix. By careful optimization of the ICP-MS instrument, it is possible to keep the formation of polyatomic species to a minimum and the elemental sensitivity close to the maximum. Isobar overlap may also be caused by doubly charged ions; such ions are detected at half mass (m/2). The elements that could produce doubly charged ions are typically the alkaline metals, alkaline earth metals, and some transition metals. Physical interferences are associated with nebulization and transport processes as well as with ion-transition efficiencies. The efficiency of the nebulization and transport processes depends on the viscosity and surface tension of the aspirated solution. Therefore, physical interference (matrix effect) may occur when

407

Analytical Procedures for Measuring Precipitation Quality

TABLE 17.3 Isotopes of the Main Heavy Metals and Some Possible Interferences Element Cr Ni

Cu Zn

Isotope Mass

Relative Abundance

52

83.76

53

9.55

58 60 61 62 64 63

67.88 26.23 1.19 3.66 1.08 69.09

65

30.91

64

48.89

66

27.81

As

75

Cd

111

12.75

114 204 206 207 208

28.86 1.48 23.6 22.6 52.3

Pb

Isobar Overlap (% Abundance)

Polyatomic Species ArC+, 35ClOH+ ClOH+ CaO 44CaO 37

58

Fe

42

46

CaO CaO

48

TiO+, ArNa+, PO2+ ArMg+ 64

Ni (1.8)

SO2+, SS+, ArMg+ ArMg+

100

Ar35Cl+ MoO+

93 114

Sn (0.66) 204Hg (6.85)

the samples and calibration standards have different matrices. In addition to matrix matching of samples and calibration standards, the use of an internal standard may reduce these problems. If there is a considerable difference in concentration between samples or standards that are analyzed in sequence, a memory effect may occur. This effect is caused by sample deposition on the cones and in the spray chamber; it also depends on which type of nebulizer is being used. The washout time between samples must be long enough to bring the system down to a blank value. Three calibration blank standards should be analyzed to establish a representative blank level, after which the calibration standards are analyzed. After calibration, the quality control standard should be analyzed to verify the calibration. The sample introduction system is flushed with rinse blank, and the blank solution is analyzed to check for carry-over and the blank level. If the blank level is acceptable, the samples can be analyzed. If the blank values are too high, the flushing of the sample introduction system and analysis of the blank solution should be repeated until an acceptable blank level is reached. The calibration blank value, which is the same as the absolute value of the instrument response, must be lower than the method’s detection limit. 17.2.3.4 Graphite Furnace Atomic Absorption Spectroscopy GF-AAS is a powerful technique suitable for trace analysis. The technique is highly sensitive (analyte amounts 10-8–10-11 g absolute), is capable of handling micro samples (5–100 mL), and has a low noise level from the furnace. Matrix effects from components in the sample other than the analyte are more serious in this technique than in F-AAS. The precision of GF-AAS is typically 5–10%. A graphite tube is located in the sample compartment of an AA spectrometer with the light from an external source passing through it. A small volume of sample is placed inside the tube, which is then heated by applying a voltage across its ends. The analyte dissociates, and the fraction of analyte atoms in the ground state absorbs portions of light. The attenuation of the light beam is measured. As the analyte atoms are formed and diffuse out of the tube, the absorption rises and falls in a peak-shaped signal.

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Analytical Measurements in Aquatic Environments

The Beer–Lambert law describes the relation between the measured attenuation and the analyte concentration. Detailed descriptions of the GF-AAS technique can be found in various textbooks.14 With this technique, problems may arise with interference, such as background absorption—the nonspecific attenuation of radiation at the analyte wavelength caused by matrix components. To compensate for background absorption, correction techniques such as a continuous light source (D2-lamp) or the Zeeman or Smith–Hieftje method should be used. Enhanced matrix removal due to matrix modification may reduce background absorption. Nonspectral interference occurs when components of the sample matrix alter the vaporization behavior of the particles that contain the analyte. To compensate for this kind of interference, the method of standard addition can be used. Enhanced matrix removal by matrix modification or the use of a L’vov platform can also reduce nonspectral interferences. Hollow cathode lamps are used for As, Cu, Cr, Ni, Pb, and Zn; single-element lamps are preferred, but multielement lamps may be used if no spectral interference occurs. Calibration standards are prepared by single or multiple dilutions of the stock metal solutions. A reagent blank and at least three calibration standards should be prepared in graduated amounts in the appropriate range of the linear part of the curve. The calibration standards must contain the same acid concentration as in the samples after processing. 17.2.3.5 Flame-Atomic Absorption Spectroscopy F-AAS is a very specific technique, subject to few interference effects. F-AAS is a single-element technique, and analyte determinations in the mg/L region are routine for most elements. A liquid sample is nebulized to form a fine aerosol, which is mixed with fuel and oxidant gases, then carried into a flame. In the flame the sample is dissociated into free ground-state atoms. A light beam from an external source emitting specific wavelengths passes through the flame. The wavelength is chosen to correspond with the absorption energy of the ground-state atoms of the target element. The parameter measured in F-AAS is the attenuation of light. Unfortunately, the detection limits (Table 17.3) are too high to make this technique very useful for precipitation samples in rural areas, except in the case of Zn, which usually has a relatively high concentration level. 17.2.3.6 Cold Vapor Atomic Fluorescence Spectroscopy The most common procedure for analyzing mercury in precipitation is oxidation with BrCl, prereduction with NH2OH ◊ HCl, followed by reduction of the aqueous Hg to Hg0 using SnCl2. Hg is purged onto gold traps, thermally desorbed, and analyzed using CV-AFS.6,15,16 The traps should be dried at about 40°C in a mercury-free N2 flow for 5 min prior to analysis, after which they should be connected to the AFS detector on-line with the helium gas flow. The mercury is then thermally desorbed either directly into the detector or onto an analytical trap. If an analytical trap is used, a second heating step should be performed before the detection. The advantages of dual amalgamation are that the influence of any interfering substances adsorbed on the first trap may be reduced and that the mercury adsorbed on the second analytical trap will be more easily desorbed, thus yielding a sharper peak. The calibration step is critical. In general, the basic principle is always to use two independent calibration solutions. One of these can be made from pure chemicals, for example, Hg0 dissolved in concentrated HNO3 and diluted to the appropriate volume. For mercury, commercially available standard solutions can be used, but regular checks against a reference standard must be made. Certified reference materials (CRFs) should be used if available, but reference standards can also be prepared from pure mercury compounds. In the absence of aqueous-phase reference standards, solid materials may be used.

17.2.4

MEASUREMENTS OF POPS IN PRECIPITATION USING GC-MS

Measurement of POPs in precipitation is a very difficult task because of problems with contamination and the very low concentration levels. Monitoring networks have usually focused on air samples,

Analytical Procedures for Measuring Precipitation Quality

409

which to some extent are easier both from an analytical point of view and with regard to applying the data to study transport and sources. Nevertheless, precipitation measurements are of great importance for a better understanding and quantification of the deposition of these compounds. GC-MS can be used to analyze organochlorine pesticides, for example, a-, b-, g-HCH, HCB, and polychlorinated biphenyls (PCB). The components are quantified by using an internal standard. Furthermore, a calibration is performed with a standard mixture containing known concentrations of the components to be measured and one or more components not contained in the sample (internal standards). The calibration is followed by injection of the sample containing known amounts of internal standards. Quantification is relative to the internal standard. In this way, the sample extract volume will not be included in the calculations, and it is not necessary to accurately determine the final sample volume after evaporation of the injection volume. The GC-MS instrument should be calibrated every day. The sensitivity of the mass spectrometer can, for instance, be controlled daily by determining the signal-to-noise ratio for a given amount of a chosen component (PCB-101 could be one such component). For further details of the method, the reader is referred to different manuals and papers on the subject.4,17

17.3

DATA QUALITY CONTROL

Measurements should be standardized as far as possible so that the data obtained are comparable and of sufficient quality. Traceability is an important concept for documenting the quality of the measurements; every standard solution must be regularly checked against a reference material. Documents describing the equipment and procedures should be available to the operators and technicians responsible for the sampling and chemical analysis, and these documented procedures should be followed to the letter. All the personnel involved should be adequately trained and instructed. Frequent use should be made of field and laboratory blanks; these are essential for discovering the weak links in the sampling, handling, and analytical procedures. The blank results should also be used to correct measurements when necessary. The detection limits for the methods need to be quantified as 3 times the standard deviations of the blanks. The chemicals used may themselves be a source of contamination for some elements and have to be checked. A clean laboratory and equipment are undoubtedly crucial to all analytical methods. For trace element and POP measurements, however, additional precautions need to be taken. Glassware and other materials used for storing samples may act as both a source and a sink for some transition and heavy metal ions. Consequently, it is important to clean glassware and polyethylene equipment several times with dilute solutions of nitric acid followed by deionized water. Gloves must be worn whenever working with samples and sampling equipment. Interlaboratory exercises have to be a part of the measurement program in order to ensure, as far as possible, a consistent data set. CRMs of artificial precipitation samples and solid samples are available from various organizations, for example, BCR, NIST, and IAEA. In addition, laboratory intercomparisons are arranged annually by, for example, WMO/GAW and EMEP. Artificial precipitation samples are distributed to different laboratories. EMEP laboratory comparisons of the main components in precipitation have been conducted for 25 years, and they have provided important documentary evidence for the evolution of data quality in EMEP during this period. The results show that laboratory performance has improved during this period, so that at present most laboratories manage to be within the 10% relative standard deviation (RSD) for all the major ions (Table 17.4). For heavy metals, laboratory intercomparisons have been conducted for about 10 years; there has been an improvement in respect of these elements, too. The relative uncertainty here, however, is greater for the major ions (Table 17.5). For some laboratories, low concentrations are particularly difficult to measure; the general problem is that detection limits are too high. Field intercomparisons are another important quality assurance step for quantifying the uncertainty of methods; they also include the sampling uncertainty and not just the analytical uncertainty

410

Analytical Measurements in Aquatic Environments

TABLE 17.4 RSD of Major Ions in the Laboratory Intercomparison in 200518 AT CH CZ DE DE Leipz DK EE ES FI FR GB HU HR IE IS IT IT LT LV MK NL NO PL PL05 PT RU SE SI SK TR YU

SO 42-

NO3-

NH 4+

pH

Mg 2+

Na+

Cl-

Ca2+

K+

Cond

0.6 0.7 0.9 0.6 0.1 0.3 1.2 6.3 0.9 0.4 0.9 2.7 1.2 0.5 2.0 1.0 0.5 3.2 2.3

0.2 0.6 0.3 0.5 0.3 0.3 1.4 7.0 1.7 0.9 0.9 2.9 2.0 1.1 6.0 0.7 3.4 0.6 2.4 9.9 3.5 0.7 0.7 2.4 2.5 6.7 0.2 2.1 1.3 2.6 0.7

1.4 1.0 10.5 1.1 0.7 1.2 32.7 4.1 2.6 1.0 1.9 1.2 0.8 2.6 11.4 3.8 11.4 3.0 1.2 89.2 0.5 1.2 3.4 0.8 4.9 1.8 2.9 2.2 38.4 11.8 1.0

0.3 0.0 0.5 0.1 0.0 0.0 1.3 0.3 0.3 0.2 0.3 0.3 0.2 0.2 0.3 0.5 1.0 0.1 0.2 1.3 0.3 0.2 0.2 0.4 0.9 0.2 0.2 0.2 0.2 0.3 0.1

3.1 1.2 1.2 0.8 0.8 1.2 2.0 0.4 2.8 3.5 18.5 0.8 9.8 2.0 2.4 2.4 1.2

1.3 0.4 2.3 1.2 0.4 5.1 2.7 1.8 11.2 1.6 15.2 2.1 3.7 1.3 0.7 3.2 0.3 2.1 0.2 1.1 2.0 1.4 2.7 0.5 4.1 10.5 0.5 1.3 5.4 2.0 1.4

4.2 1.1 1.3 0.9 0.8 3.2 4.1 12.0 9.6 2.1 1.8 18.2 1.3 1.8 12.5 3.3 3.6 3.1 6.8

2.8 0.7 3.2 0.7 0.5 3.0 6.7 1.0 2.3 3.5 6.2 22 8.8 2.0 1.5 1.8 1.7 45.1 1.8 183.1 1.8 1.5 3.7 0.8 3.5 24.1 2.8 1.3 13.5 4.5 2.2

1.6 2.9 1.3 1.0 0.3 2.1 0.8 0.7 2.8 1.3 10.3 8.5 8.3 2.1 5.2 2.8 9.5 1.6 0.7 7.1 7.0 0.5 4.1 0.8 5.4 7.8 0.7 0.3 17.3 3.6 1.3

0.9 0.3 1.2 3.0 1.4 1.8 3.1 0.9 0.8 1.9 4.0 2.1 1.1 0.4 1.6 2.1 1.2 1.0 0.6 16.6 1.2 1.4 1.0 1.3 1.9 0.9 1.4 1.3 0.5 6.6 0.5

0.5 0.5 0.9 1.5 11.2 3.9 0.1 0.6 4.5 0.7 0.4

5–10%

1.6 31.3 3.9 3.5 2.0 0.4 5.1 9.1 2.4 2.0 10.2 4.7 2.8

10–25%

5.6 1.1 1.6 2.5 22.3 31.0 1.4 7.0 3.9 2.9 2.1

>25%

that is measured in the laboratory intercomparison. This is especially important in the initial phase of the measurement program so as to prevent erroneous data being produced over a long period of time. For example, a comparison between bulk- and wet-only collectors should be done if the bulk collector is the preferred one, in order to evaluate the influence of dry deposition.

17.4 FUTURE PERSPECTIVES The analytical methods for the main ions and heavy metals are well established and there is no special need for further improvements. The greatest uncertainties in these methods lie in the sampling procedures and site representativeness. For POPs, reference methods are at present available only for air measurements; such methods need to be established for precipitation samples as well. Even though the analytical method may be the same, sample preparation and the sampling itself

411

Analytical Procedures for Measuring Precipitation Quality

TABLE 17.5 RSD of Heavy Metals in 20062 As Lab

Cd

Low

High

1

4

2

2 3 4

12 15 25

4 1 11

5 6

21

20 2

7 8 10 13 14 15 16 23 32 33 36 38 39

8

Cr

Cu

Ni

Low

High

Low

High

High

Low

High

4

3

6

0

4

0

3

3 7 11

26 7

22 25 100

10 14 34

1 5 15

5 0 21

13

12

2 12 26 11

7

8

9

11 11

2 17

2 2

3

2

3



6 8

16

4

10

2 1 0

51

7 2 0

3 25

3 1 4

3 1 0

1 6 9

2 2 3

18 23 15 5

20 10 9 7

6 13 10 2 3

5 21 3 1

4 3 3 1 7

2 19 4 10 21

3 4 6 10 3

3

6

5

1

0

2 5 1 4 12


0


0

10–25% RSD

1

Low

Pb

25–50% RSD

0

Zn

Low

High

Low

High

5

12 1

14 4 31 8

5

1

2 11 9 11
1 5 18 2 9


0

11

4 11 0

3 3 4

4 6 9 1
7 5 9 7 90


0

>50% RSD

Note: DL means lower than the detection limit, and low and high indicate concentration levels of the sample.

need meticulously elaborated operating procedures. Furthermore, there might be a need to include other species, such as phosphate, organic acids, and black carbon. The last two are important for studying carbon fluxes, and phosphates are significant in the nutrient balance. Standardized protocols for these compounds may be developed in the future.

ACKNOWLEDGMENTS The methods described in this chapter have been developed continuously since 1977, the beginning of the EMEP Programme. There are many scientists who have contributed to defining reference methods for EMEP: I would especially like to mention Jan Erik Hanssen, Jan Schaug, Arne Semb, and Hilde Thelle Uggerud.

REFERENCES 1. Hjellbrekke, A.G. 2008. Data Report 2006. Acidifying and eutrophying compounds and particulate matter. EMEP/CCC-Report 1/2008. 2. Aas, W. and K. Breivik. 2008. Heavy metals and POP measurements 2006. EMEP/CCC-Report 4/2008. 3. UN-ECE. 2004. EMEP Monitoring Strategy and Measurement Programme 2004–2009, EB.AIR/ GE.1/2004/5. 4. EMEP. 2001. Manual for Sampling and Chemical Analysis. Revised November 2001. Kjeller, Norway: Norwegian Institute for Air Research. EMEP/CCC Report 1/95. URL: http://www.nilu.no/projects/ccc/ manual/index.html.

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Analytical Measurements in Aquatic Environments

5. WMO/GAW. 2004. Manual for the precipitation chemistry programme. WMO Report No. 160. 6. Munthe, J. 1996. Guidelines for the sampling and analysis of mercury in air and precipitation. Gothenburg. IVL-Report L 96/204. 7. OSPAR. 1997. JAMP guidelines for the sampling and analysis of mercury in air and precipitation. London. 8. Weiss, J. 1994. Ion Chromatography, 2nd edition. Weinheim: Wiley-VCH. 9. ISO. 1992. ISO norm 10304-1, publication date 1992-11. Method for determination of soluted anions fluoride, chloride, nitrite, o-phosphate, bromide, nitrate, sulphate with liquid ion chromatography: Low polluted water. 10. Fisons Scientific equipment, VG Instrument Group, Bulletin No. 5M/AMSG/390, England. 11. Perkin Elmer, “new AnalystTM 800 detection limits,” Technical note, Norwalk, USA, 1998. 12. Parsons, M.L. and A.L. Forster. 1983. Trace element determination by atomic spectroscopic methods— state of the art. Appl. Spectros. 37: 411–418. 13. Jarvis, K.E., A.L. Gray, and R.S. Houk. 1992. Handbook of Inductively Coupled Plasma Mass Spectrometry. Glasgow: Blackie. 14. Montaser, A. 1998. Inductively Coupled Plasma Mass Spectrometry. New York: Wiley. 15. Bloom, N.S. and E.A. Crecelius. 1983. Determination of mercury in seawater at subnanogram per litre levels. Mar. Chem. 14: 49–59. 16. Bloom, N.S. and W.F. Fitzgerald. 1988. Determination of volatile mercury species at the picogram level by low temperature gas chromatography with cold-vapour atomic fluorescence detection. Anal. Chim. Acta 208: 151–161. 17. Vogelsang, J. 1991. The quality control chart principle: Application to the routine analysis of pesticide residues in air. Fresenius J. Anal. Chem. 340: 384–388. 18. Aas, W. 2007. Data quality 2005, quality assurance, and field comparisons. EMEP/CCC-Report 3/2007.

18

Life Cycle Assessment of Analytical Protocols Helena Janik and Justyna Kucin´ska-Lipka

CONTENTS 18.1 General Idea of LCA ........................................................................................................ 18.2 Methodology of LCA ........................................................................................................ 18.2.1 Goal and Scope ..................................................................................................... 18.2.2 LCI Analysis ......................................................................................................... 18.2.3 Life Cycle Impact Assessment .............................................................................. 18.2.4 Life Cycle Interpretation and Application ............................................................ 18.3 LCA for Solvent Use in Analytical Protocols ................................................................... 18.4 Conclusions ....................................................................................................................... Acknowledgments ...................................................................................................................... References ..................................................................................................................................

18.1

413 415 415 416 418 421 424 427 428 428

GENERAL IDEA OF LCA

Life cycle assessment (LCA) is a relatively new tool for environmental management, which is becoming more and more important owing to the globalization of the world economy, where there is a need to develop standards in protecting the environment. LCA is one of the most valuable analytical tools that governments, businesses, and environmentalists can use to assess the environmental load and impact caused by any kind of human undertaking on the Earth. LCA originated in the early 1970s. At the beginning, studies in this field were carried out in only a few countries—Sweden, the United Kingdom, Switzerland, and the United States. The products that dominated LCA discussion for a long time were beverage containers.1 Later, in the 1970s and the 1980s, more studies were carried out using different methods but without a common theoretical framework. The consequences of this approach were negative, as the results differed greatly, even though the objects of the study were the same. This is what prevented LCA from becoming a more generally accepted analytical tool. Moreover, these results were taken up by firms in order to substantiate marketing claims. Since about 1990, under the coordination of the Society of Environmental Toxicology and Chemistry (SETAC), the discussion and exchange of ideas between LCA experts has increased, and efforts have been undertaken to harmonize the methodology and establish a “Code of Practice.”2 Complementary to the efforts of SETAC, the International Organization for Standardization (ISO) (Technical Committee 207, Subcommittee 5) has played a role in LCA improvement since 1994. While SETAC has focused on the development of methodology, the ISO has begun work on its standardization (ISO 14040, 1997 E, ISO 14041, 1998E, ISO 14042, 2000E, and ISO 14043, 413

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Analytical Measurements in Aquatic Environments

From cradle

To grave

Energy

Energy

Raw materials acquisition

Wastes

Energy

Energy

Energy

Materials manufacture

Product manufacture

Product use or consumption

Wastes

Wastes

Wastes

Final dispositionlandfill, incineration recycle, or reuse

Wastes

Reuse Product recycling

FIGURE 18.1 The general material and product flow showing the idea of LCA—“From the Cradle to the Grave.” (Reworked on the basis of ISO 14 040.3)

2000E). LCA3,4 is a method used to identify the authentic environmental impact of a product (material, service), taking into account its effect on the environment at every stage of its life cycle (the “From the Cradle to the Grave” viewpoint—Figure 18.1). It attempts to analyze each step in the life cycle of products, services, or activities by identifying the energy, materials, and other components used in order to assess their impacts on the environment. This applies to the impact caused by the extraction of raw materials (e.g., energy and water usage, farming practices, renewable resources, and greenhouse gas emissions), through their processing into the final product, transporting the product, using (and reusing) it, and its eventual disposal (including residues and greenhouse gas potentials) or recycling. The intention of LCA is to present a methodology and framework within which quantitative criteria to support policy decisions can be generated on a systematic basis. These criteria encompass the set of materials and energy inputs and outputs of the life of a product, process, or activity. LCA results are the background to be considered in the actions for the conversion of current production and consumption (in a broad sense) patterns to environmentally less burdensome patterns. LCA is currently being implemented by industry to help governments establish certification criteria for different fields. There is already quite a substantial literature on the LCA of materials or processes, for example: • LCA of the anaerobic digestion of waste products5 (comparison of anaerobic and aerobic digestion processes) • LCA of forestry products6 (watchdogs for the sustainable harvesting of forestry products) • LCA of extractive industries7 (minimization of environmental threats) • LCA of communal waste8 • LCA of product impact on the environment9 • LCA of ship lifetime10 In this chapter we shall discuss LCA in the context of protocols for the analysis of polychlorinated biphenyl (PCB) and polycyclic aromatic hydrocarbon (PAH) in surface water using two different extraction techniques,11 and the LCA of the utilization of different solvents.12–26 Generally speaking, this is the beginning of the use of LCA to assess the environmental impact of analytical protocols; at the moment, there are not many papers on this subject, but this situation is sure to improve in the near future.

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Life Cycle Assessment of Analytical Protocols

18.2

METHODOLOGY OF LCA

According to ISO 14040-14049, LCA should consist of the following four fundamental and separate phases (Figure 18.2): 1. 2. 3. 4.

Definition of goal and scope Life cycle inventory (LCI) analysis Life cycle impact assessment (LCIA) Life cycle interpretation.

18.2.1

GOAL AND SCOPE

In this first phase of LCA, the following aspects must be defined/described: the purpose and extent of the assessment; the descriptive functional unit (represented by a product or service) that is formed and its limits; the basis of comparison; the components of the product’s life cycle; and assumptions and possible limitations.

CASE STUDY Assessment goal: Identification of the main streams of environmental loading in the phases of materials production and extraction processes with two different preparation techniques applied to the analysis of PCB and PAH in surface water.11 Assessment scope: Comparison of liquid–liquid extraction (LLE) and solid-phase extraction (SPE). Functional group: The preparation, over a period of 10 years, of 30,000 final extractions (27,500 samples—water analysis, 2500—blank analysis) to establish the amount of PCB and PAH in surface water using gas chromatography with an attached mass spectrometer (GC-MS). Limitation: This particular analysis is demonstrated for scientific and teaching reasons; marketing purposes are thus excluded. System studied: Figure 18.3 shows a diagram of the elements of the product cycle (here: a service) for both systems studied. Assumptions: Elements that are the same for both techniques (e.g., syringes and pipettes) are excluded from the LCA.

Goal and scope definition

Applications: – Product development and improvement – Planning

Inventory analysis

LCA interpretation

– Policy decision (enterprises, government, society) – Marketing – Education

Impact assessment

FIGURE 18.2 Life cycle assessment phases and the use of results. (Reworked according to ISO 14040.3)

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Analytical Measurements in Aquatic Environments

SPE extraction

LLE extraction

Raw materials acquisition

Raw materials acquisition

Devices/solvents production

Transport

Material and energy exchange with environment

Procuct manufacture

SPE extraction

Procuct manufacture

Devices/solvents production

Transport

LLE extraction

Final extracts

FIGURE 18.3

A general view of the systems (case studies) with their life cycles.11

18.2.2 LCI ANALYSIS The second phase of LCA considers the collection and quantification of system inputs and outputs that are of extreme environmental importance (land use, emissions, waste generation, and use of resources).27–30 Inputs include the materials and energy entering the system studied, whereas outputs take the form of energy, materials, emissions, and waste products that cross over from the system to the environment.3,4 There are many programs (Umberto, GaBi, TEAM, Eco Manager, Eco Pro, Chalmers, EarthShift, ATROiD, SimaPro, and others not mentioned here) for doing LCA, including the construction of inventory tables and impact assessment with the aid of a computer.

CASE STUDY: CONTINUATION OF THE ABOVE ANALYSIS WITH THE USE OF SimaPro 6.04 The first step in this phase, with the use of the computer procedure, is to create all the input and output data using the database library and one’s own information (Tables 18.1 through 18.4). From the database library, one can select the relevant data for material, energy, transport, processing, and so on. In this way the model assembly can be constructed, taking into account all the elements of the system studied. An assembly contains a list of materials and production processes, as well as transport processes. Assemblies do not contain environmental data; instead, they link to processes that contain such data. Some parts, such as the mains cable, can be defined in subassemblies. A convenient way to visualize the structure and contents of an assembly is to use the “process tree” function (Figure 18.4).

417

Life Cycle Assessment of Analytical Protocols

TABLE 18.1 Input Elements for SPE Method11 Element Glass vacuum chamber Polyamide cover Polyethylene sealings Polytetrafluoroethylene (“teflone”) taps Polytetrafluoroethylene (“teflone”) drains Polytetrafluoroethylene (“teflone”) stand Polytetrafluoroethylene (“teflone”) adapters Polypropylene extraction tiny columns Metal pump Dichloromethane Methanol Deionized water Washing deionized water Washing acetone Washing dichloromethane Running water Nitrogen Energy Transport 1 (solvents) Transport 2 (pump) Transport X (etc.)

Amount

Mass (g)

1 1 10 120 60 1 60 30,000 1 — — — — — — — — 1000 kWh 1008 km 1259 km …

1800 841 7.2 614 574 283 315 66,480 5000 518,700 142,200 90,000 300,000 237,000 399,000 1,000,000 554,000 — 1,296,000 5000

Volume (L) (for Solvents) — — — — — — — — — 390 180 90 300 300 300 1000 — — — — —

…

Once a product assembly has been defined, SimaPro can immediately calculate the socalled LCI results or inventory table (Table 18.5). This is a list of all raw material extractions and emissions that occur in the production of the assembly and the materials and processes that link to it. SimaPro enables the LCI results to be specified as one table or per compartment, such as airborne or waterborne emissions. The LCI results provide the most detailed level of specification. At this step of LCA, it is not easy to interpret these long lists of data, as it is unclear what the environmental relevance of each raw material extraction or emission is. ISO 14042 on impact assessment specifies a number of procedures that can be used to achieve a better understanding of LCI results.

TABLE 18.2 Output of Elements for SPE Method (Wastes to the Environment)11 Type Dichloromethane Methanol Acetone Nitrogen

Mass (kg) 532 142 237 554

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Analytical Measurements in Aquatic Environments

TABLE 18.3 Input Elements for LLE Method11 Element Glass separator Polytetrafluoroethylene (“teflone”) parts Polyethylene parts Dichloromethane Washing deionized water Running water Washing dichloromethane Washing acetone Nitrogen Transport 1 (glass separator) Transport (solvents) Transport X (etc.)

Amount

Mass (g)

15 2 2 — — — — — — 10,008 km 10,008 km …

5,190,000 566 148 119,700 15,000,000 45,000,000 300,000 300,000 1,756,000 5,804,000 119,700 …

Volume (L) (for Solvents) — — — 900

—

TABLE 18.4 Output of Elements for LLE Method11 Type Dichloromethane Acetone Nitrogen

18.2.3

Mass (kg) 1497 300 1756

LIFE CYCLE IMPACT ASSESSMENT

This element plays a crucial role in the whole LCA as it assesses the influences of environmental impacts (interventions) in regard to the results of LCI analysis. Its goal is to examine the product from the environmental point of view using information collected through LCI analysis. Many aspects during the whole life cycle of the system under consideration can be analyzed. This can be done for the production step, the processing step, recycling of wastes, solvent use, and solvent emission, and in the end one can analyze the entire life cycle. There are many different impact assessment methods to choose from; they are denoted in the literature by characteristic abbreviations, for example, CML92, CML2-2000, Eco-indicator 95, Ecopoints-Swiss 97, Eco-indicator 99, EDIP/ UMIP 96, EDIP 99, EPS 2000, and IMPACT 2002+. The results of LCIA are shown for all impact categories in different ways: characterization, normalization, weighting, and single score (accumulated indicator). Table 18.6 shows the environmental impact categories.27–30 The categories may differ (Table 18.7) with respect to the LCA of different products (or the object of LCA) or assessment methods.12–14 For every impact category the proper category indicator is calculated.

CASE STUDY: CONTINUATION With the inventory tables (Table 18.5) drawn up in the previous phase of LCA in mind, it is time to move on to the next step, which is called characterization. The results of this step are presented in a graph showing a number of impact category indicator results calculated from the LCI results. It is an obligatory step in impact assessment. In this example, we use the

419

Life Cycle Assessment of Analytical Protocols 3E4 p Extracts SPE 589

931 kg Dichloromethane 194

3,6E3 MJ Electricity, low 52,1

4E3 MJ Electricity medium 49,8

156 kg Petrol unleaded 31,1

4,04E3 MJ Electricity high 49,4

156 kg Petrol unleaded 31,1

4,06E3 MJ Electricity 49,3

1,41 E3 km Delivery van 194

237 kg Acetone, liquid, at 65,9

1,41E3 km Infra delivery 36,2

174 kg Petrol leaded stock 36,3

175 kg Petrol leaded 34,7

226 kg Crude oil transport 35,6

301 kg Crude oil

376 kg Crude oil

46,7

59,2

FIGURE 18.4 The “process tree” used for the assembly created in SimaPro for SPE analytical protocol.11

Eco-indicator 99 method, but it is also possible to choose one of the other methods that are available in SimaPro. All the results of this step of LCIA are scaled to 100% (Figure 18.5). Each bar (column) represents the impacts arising from different subassemblies of the analytical protocol studied. With all impact category indicator results scaled to 100%, it is not easy to see which parts of the assembly have the highest overall environmental impact. Each bar on the histogram could represent 100% of a very large impact, or, equally, 100% of a small one. To obtain a better picture, the normalization procedure is used (Figure 18.6). Normalization is an optional step in impact assessment. The impacts are now compared on a scale of inhabitant equivalents rather than that of 100%. Normalization only reveals which effects are large and which effects are small in relative terms. A weighting procedure (Figure 18.7) can be applied to the normalization results. This scales the results to a certain level of seriousness. Weighting is a subjective step. According to ISO 14042, weighting may not be used in the case of public comparisons between products. In the final step, SimaPro can add up all the evaluation scores to give a total impact score for each subassembly element.

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Analytical Measurements in Aquatic Environments

Table 18.5 Inventory Table for SPE Technique Created in SimaPro11 Material

1

Teflon Glass Polyamide (PA) Polyethylene (PE) Polypropylene (PP) Gel Dichloromethane Methanol Steel Azote Water millipore Dichloromethane washing Acetone Running water Energy Transport

2195 g 1800 841 7.2 g

2

3

4

0 2600

500 g

2.6 kg 66.5 kg 15 kg

400 g

5

6

518 kg 142 kg

399 kg 5 kg 554 kg 500 13.3 kg

90

300 kg

1.6 tkm

84.8 tkm

666 tkm

Impact Category Carcinogens Respirability organics Respirability inorganics Climate change Global warming Radiation Ozone layer Human toxicity Ecotoxicity Photochemical oxidant Acidification Eutrophication Degradation of ecosystems Degradation of landscapes Land use Resource depletion⎯abiotic and biotic Minerals Fossil fuels

b c

2695 g 4400 g 841 g 3021 g 66.5 kg 15 kg 919 kg 142 kg 5 kg 554 kg 890 kg 13.3 kg

237 kg

7.4 tkm

1000 kg 1000 kWh 13.4 tkm

641 tkm

TABLE 18.6 Environmental Impact Categories Considered in LCA

a

Amount

Unit DALYa DALY DALY DALY DALY DALY DALY PAF*m2 yr PAF*m2 yr PAF*m2 yr PDF*m2 yrb PDF*m2 yr PDF*m2 yr PDF*m2 yr PDF*m2 yr MJ surplusc MJ surplus MJ surplus

DALY, disability adjusted life years. PDF, potentially disappeared fraction of plant species. MJ surplus, additional energy requirement to compensate for lower future ore grade.

1000 kg 1000 kWh 1414 tkm

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Life Cycle Assessment of Analytical Protocols

TABLE 18.7 Impact Categories Comparison between Eco-Indicator 9912 and Impact 2002+14 Eco-Indicator 99

Impact 2002+

Carcinogens (C)

Carcinogens Noncarcinogens Respiratory inorganics Respiratory organics Global warming potential (GWP) (DF) Ozone depletion potential Aquatic and terrestrial toxicity Terrestrial acidification and nutrification GWP (CF) Aquatic acidification Terrestrial eutrophication Resource (energy) Resource (mineral)

Respiratory inorganics (RI) Respiratory organics (RO) Ozone depletion potential (OL) Ecotoxicity (E) Acidification and eutrophication (A/E)

Resource (energy) (R) Resource (mineral) (R) Radiation (R) Land use (LU) Resource (fossil fuels) (FF) Climate change (CC)

18.2.4

LIFE CYCLE INTERPRETATION AND APPLICATION

In the final phase of LCA, inferences are drawn especially from LCI analysis and LCIA. From an analysis of the results, conclusions can be drawn and limitations defined, and recommendations for producers and policy-makers can be made. In general, the purpose of an LCA is to make inferences that can support a decision or provide a basis for a viewpoint. This means that the process of drawing conclusions is perhaps the most important step in any LCA. The relevant issue of interpretation is dealt with in ISO 14043. This phase will be exemplified as a case study comparing the results of LCA for two analytical protocols.

120 100

%

80 60 40 20 0 C

RO D

RI

CC S

R P

OL A

E C

A/E LU T

W

M

FF

DC

FIGURE 18.5 Characterization graphs in the LCIA phase of LCA with all impact categories for SPE11 (D, device; S, solvent; P, pump; A, nitrogen; C, columns; T, transport; W, washing; and DC, drain cleaning; for the remaining abbreviations, see Table 18.7).

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Analytical Measurements in Aquatic Environments 2

1

0

C

RO

RI

D

CC S

R P

OL A

E

A/E LU

C

T

M

W

FF DC

FIGURE 18.6 Normalization step in the LCIA phase of LCA for SPE11 (D, device; S, solvent; P, pump; A, nitrogen; C, columns; T, transport; W, washing; and DC, drain cleaning; for the remaining abbreviations, see Table 18.7). 250

Pt

200 150 100 50 0 C D

RO S

RI

CC P

R

OL A

E C

A/E LU T

M E

FF DC

FIGURE 18.7 Weighting step in the LCIA phase of LCA for SPE11 (D, device; S, solvent; P, pump; A, nitrogen; C, columns; T, transport; W, washing; and DC, drain cleaning; for the remaining abbreviations, see Table 18.7).

CASE STUDY: COMPARISON OF TWO DIFFERENT ANALYTICAL TECHNIQUES (SERVICES—SPE AND LLE—USING THE ECO-INDICATOR 99 METHOD IN SimaPro From Figure 18.8 it is clear that all kinds of impact categories are involved in both extraction techniques. At this stage of the assessment, it looks as if SPE has the lower environmental load in almost all categories with the exception of minerals. This emerges directly from the types of devices used in SPE, as opposed to LLE, where only a simple glass separator is used. After normalization of the results (Figure 18.9), three impact categories turned out to be very important for both techniques: fossil fuels, respiratory inorganic, and climate change. According to the normalization graph, the environmental load of SPE is slightly lower than that of LLE. It is also possible to display the results for one product with all the categories in one graph (Figure 18.10). This way of presenting results is very useful for comparing two different products (here: extraction techniques). From Figure 18.10 it is again clear that the environmental load of SPE is lower than that of LLE. Similar steps in the LCIA of LCA can be done to assess the damage category (human health, ecosystem quality, and resources). Figure 18.11 shows the details of the LCIA phase for these assessment categories. Table 18.8 compares the quantitative impact and damage categories for the two different extraction techniques.

423

Life Cycle Assessment of Analytical Protocols 120 100

%

80 60 40 20 0 C

RO

RI

CC

R

OL

LLE

E

A/E LU

M

FF

SPE

FIGURE 18.8 Characterization graphs of the LCIA phase in LCA for two analytical techniques (SPE and LLE) used to estimate PCB and PAH in surface water.11

2

1

0

C

RO

RI

CC

R

OL

LLE

E

A/E

LU

M

FF

SPE

FIGURE 18.9 Normalization graphs of the LCIA phase in LCA for two analytical techniques (SPE and LLE) used to estimate PCB and PAH in surface water.11

700 600

Pt

500 400 300 200 100 0

C

RO

LLE RI

CC

R

SPE OL

E

A/E

LU

M

FF

FIGURE 18.10 Environmental loading for all impact categories: for two different extraction techniques with the use of LCA in SimaPro and Eco-indicator 99 (single score).

424

Analytical Measurements in Aquatic Environments (a) 120

(b) 2

100

kPt

%

80 60

1

40 20 0

0 HH

EQ SPE

LLE (c)

HH

R

EQ LLE

R SPE

(d)

0.5

700 600 500 kPt

400 300 200 100 0

0 HH

EQ LLE

R SPE

LLE C

RI

CC

SPE E

A/E

FF

FIGURE 18.11 Comparison of LCIA results for SPE and LLE techniques used to estimate PCB and PAH levels in surface water within damage categories: (a) characterization graphs, (b) normalization graphs, (c) results of LCIA after weighting, and (d) results of LCIA-cumulated indicator (single score).

The comparison of two extraction techniques with the use of LCA allows one to assess which technique is the more environmentally friendly and which impact or damage categories carry the heaviest environmental load. The results can be used in many ways, for example, to modify elements of the devices used, to estimate the amount and the environmental loading of the solvent to be used in both techniques, and to consider modifications of the techniques used in a particular laboratory.

18.3 LCA FOR SOLVENT USE IN ANALYTICAL PROTOCOLS Nowadays, solvents are used in large quantities in the chemical industry and chemical laboratories. The selection of solvents and subsequent waste-solvent management are based mostly on considerations of economy, safety, and logistics. Environmental concerns are often of minor importance for decision-makers.

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Life Cycle Assessment of Analytical Protocols

TABLE 18.8 Quantitative Data for Impact Categories and Damage Categories for Two Different Extraction Techniques11 Category

Environmental Loading (Pt)

Category

Environmental Loading (Pt)

Damage category

LLE

SPE

Impact category

LLE

SPE

Human health

371

266

Resources Ecosystem quality

329 58.3

275 47

Respiratory inorganic Climate change Fossil fuels Ecotoxicity Acidification/eutrophication

230 109 327 32 21

180 64 273 27 16

Note: Results of LCA with the use of Eco-Indicator 99 in SimaPro program—teaching use.

The use of a solvent in any application is associated with a variety of indirect environmental impacts, such as the depletion of nonrenewable resources as a consequence of petrochemical production, atmospheric emissions as a result of solvent incineration, or the high energy demand for solvent recycling by distillation.18–21 The assessment of a solvent’s environmental impact should consider not only impacts arising from its industrial production, recycling, and disposal, but also its ESH (environmental, safety, and health) characteristics. This kind of thinking has led to the idea of a “green solvent” or ecosolvent.22,31–33 Four approaches toward green solvents have been developed recently: • The substitution of hazardous solvents by those with better EHS properties, such as enhanced biodegradability or low ozone depletion potential23–25 • The use of “biosolvents,” that is, solvents produced from renewable resources (starch and cellulose26), so that the use of fossil resources can be avoided • The substitution of organic solvents by supercritical fluids with a consequent reduction in ozone depletion34 • The substitution of organic solvents by ionic liquids that have a low vapor pressure and are thus less likely to be emitted into the atmosphere34,35 Numerous solvents are also used in the analysis of aquatic media (Table 18.9), so the “green chemistry” approach in this field is highly appropriate. Capello et al.16 applied LCA to 26 organic solvents (acetic acid, acetone, acetonitrile, butanol, butyl acetate, cyclohexane, cyclohexanone, diethyl ether, dioxane, dimethylformamide, ethanol, ethyl acetate, ethyl benzene, formaldehyde, formic acid, heptane, hexane, methyl ethyl ketone, methanol, methyl acetate, pentane, n- and isopropanol, tetrahydrofuran, toluene, and xylene). They applied the EHS Excel Tool36 to identify potential hazards resulting from the application of these substances. It was used to assess these compounds with respect to nine effect categories: release potential, fire/explosion, reaction/decomposition, acute toxicity, irritation, chronic toxicity, persistency, air hazard, and water hazard. For each effect category, an index between zero and one was calculated, resulting in an overall score between zero and nine for each chemical. Figure 18.12 shows the life cycle model used by Capello et al.16 One functional unit was defined as the use of 1 kg of solvent as a reaction medium in a chemical production process. To calculate the environmental impact of specific solvents, the EcosolventTool31 was used, which combines the LCIs of 45 petrochemical products. Overall high scores for formaldehyde, dioxane, formic acid, acetonitrile, and acetic acid were obtained. Formaldehyde scored relatively low for fire/explosion hazards but high with regard to

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Analytical Measurements in Aquatic Environments

TABLE 18.9 Examples of Solvent Use in Chemical Analysis of Aquatic Environments Chemical Analyzed Azote (nitrate) Cyanides Zinc Chlorine dioxide Phosphates Iodides Molybdenum Naphtha products Mercury Selenium Silver

Method

Solvent Use

Colorimetry 1. Colorimetry 2. Argentometric titration Colorimetry Iodometry Colorimetry 1. Colorimetry 2. Titration 1. Colorimetry 2. Atomic absorption spectrometry (ASA) IR Ditizone method Colorimetry Colorimetry

Chloroform, ethanol 1. n-butyl alcohol or isoamyl alcohol 2. Chloroform, hexane or iso-octane Carbon tetrachloride Chloroform Benzene isobutanol Chloroform Ethanol Isoamyl acetate or another Organic solvent Carbon tetrachloride Chloroform Toluene Acetone, carbon tetrachloride, or chloroform

acute and chronic toxicity, irritation, and air hazard. Dioxane had a high persistency, while both acetic acid and formic acid scored high on irritation. Low overall scores were obtained for methyl acetate, ethanol, and methanol: the environmental hazards they represent are particularly low and the health hazards relatively low. The use of tetrahydrofuran, butyl acetate, cyclohexanone, and 1-propanol is not recommended for a life cycle perspective: these solvents have a high environmental impact, especially during the production of petrochemicals. At the other end of the scale, hexane, heptane, and diethyl ether are the most environmentally favorable solvents. Capello et al.16 also assessed the environmental impacts of the life cycles of four solvent mixtures (methanol–water, ethanol–water, methanol–ethanol, and n-propyl alcohol–water of different compositions w/w) that can be used for the solvolysis of p-methoxybenzoyl chloride. Different waste treatment scenarios for these binary mixtures (incineration and distillation) were analyzed. It appears that a solvent mixture with a high water content has a low environmental impact because the cumulative energy demand (CED) for the production of water is about three orders of magnitude lower than that for organic solvents.37

Waste solvent incineration

Model overview Petrochemical solvent production

Use of solvents (reaction media) Process integrated recycling

Waste solvents

Steam Electricity Fossil fuel Ancillaries Steam Electricity

Waste solvent distillation Recovered solvent

Waste solvent incineration Steam Electricity Fossil fuel

Disposal Sewage plant

Incineration

Avoidance of fossil fuels Avoidance of petrochemical solvent production Distillation Both treatment options enable a reduction of the demand of nonrenewable resources

FIGURE 18.12

System model for solvent assessment using the life cycle assessment method.14

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Therefore, the solvent mixtures with water as a component are superior to the methanol–ethanol mixture. Generally, incineration as a treatment option is superior to distillation for these solvent mixtures, particularly for those containing a high proportion of water. Only with regard to the n-propyl alcohol–water mixture is distillation the better treatment option, especially for high concentrations of this alcohol, because of its high environmental impact in petrochemical production.

18.4

CONCLUSIONS

In spite of the on-going development of LCA as an environmental tool, there is still very little available information on LCA for analytical protocols. There are drawbacks to the existing LCA programs, which mean that the information they furnish is incomplete. Nonetheless, a number of research projects are currently focused on LCA, which is sure to become an essential tool in environmental protection. Even though LCA is an excellent environmental tool in concept, in practice, it is still hard to tell whether it can be applied quantitatively. This is because there are no universal standards of comparison; in any case, the precise environmental costs, not to mention the practical ones, are hard to estimate. The aim of LCA is to reduce the overall environmental impact by providing directional environmental indicators. These should be examined carefully using other analytical techniques.38,39 However, minimizing the impacts of subsystems does not ensure that the impacts of an entire system are minimized or even reduced.40 In many cases, a reduction or change in one part of the system merely shifts the burden. Thus, the results obtained by LCA for a particular product must be analyzed very carefully before final conclusions can be drawn about the environmental impact of the product. For example, methyl tertiary butyl ether (MTBE) is a fuel additive, initially introduced in the late 1970s as an octane booster.41 By reducing the vapor pressure of gasoline, MTBE reduces emissions of carbon monoxide (CO), other products of incomplete combustion, and evaporative emissions. Reformulated gasoline containing MTBE is especially effective in reducing emissions in older vehicles when engines are cold and subjected to heavy loads. However, one physical property of MTBE not possessed by most other petroleum hydrocarbon (HC) additives is its excellent solubility in water; its transport is therefore not limited to groundwater as a result of soil adsorption. In the event of a gasoline spill, other HCs would tend to stay put, whereas MTBE would travel relatively quickly, potentially polluting nearby lakes, streams, and drinking water sources. It has also been found that MTBE is an animal carcinogen with the potential to cause cancer in humans.40,42 Despite the potential carcinogenicity and the physical properties of MTBE, a recent LCA study concluded that reformulated gasoline containing MTBE had a significant advantage over conventional gasoline as far as the reduction of hazardous air pollutants was concerned. Moreover, the study’s conclusion resulted in the recommendation that “MTBE blended gasoline be considered for use in areas where population density is relatively high and concerns regarding hazardous air pollutants exist.”43 Now, the findings and recommendations of this study are not false within the context of reducing hazardous air pollutants. But the study presented in the chapter did not consider the scenario of increased potential harm to humans and the impact on the environment via the groundwater pathway. The study focused solely on the problem to be solved, namely, the reduction of hazardous air emissions. Hence, it is very important to examine the scope and aim of the LCA results. Sometimes there is lack of information on the influence of data pertaining to other media, that is, soil and water.44 Although the study’s recommendations were correct within the context of reducing hazardous air pollutants, they may have serious environmental repercussions should a potential carcinogen enter drinking water supplies.42 The boundaries of the LCI and the LCIA were clearly stated by the study. What remained implicit was the boundaries of the recommendations, and the shortcoming of the study was that the recommendations did not explicitly describe the context that they targeted. LCA shows precisely that the price one pays for a product rarely reflects the environmental cost of producing it.

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It is worth noting that in Europe more and more governmental organizations are drawing attention to the significance of developing LCA. The Council of the European Union, for instance, is promoting just such an approach.

ACKNOWLEDGMENTS We are indebted to Lidia Wolska and Jacek Namies´nik for the consultations they kindly held with us.

REFERENCES 1. Udo de Haes, H. 1993. Application of life cycle assessment: Expectations, drawbacks and perspectives. J. Cleaner Prod. 1: 131–137. 2. Consoli, F., D. Allen, I. Boustead, et al. 1993. Guidelines for life-cycle assessment: A “Code of Practice”, J. Séguin and B. Vigon (eds). Report of SETAC Workshop—Sesimbra, Portugal, March 31 to April 3. Society of Environmental Toxicology and Chemistry (SETAC), Sesimbra, Portugal. 3. ISO 14 044 (DIN EN ISO 14040). 2006. Environmental management—life cycle assessment—principles and framework. 4. Boguski, T., R. Hunt, J. Cholakis, and W. Franklin. 1996. LCA Methodology. In: M. Curran (ed.), Environmental Life-cycle Assessment, pp. 21–37. New York: McGraw-Hill. 5. Raysoni, A. 2002. Life cycle assessment for anaerobic digestion of waste products. Int. J. LCA 7: 187. 6. Verma, M., S. Dubey, and R. Bharadwaj. 2002. Application of life cycle assessment to forestry products. Int. J. LCA 7: 187–188. 7. Durucan, S. and A. Korre. 2000. Life cycle assessment of mining projects for waste minimization and long term control of rehabilitated sites. Proceedings of the 3rd Annual Workshop EUROTHEN, p. 257. 8. De Boer, J., J. Jager, E. Szpadt, et al. 2003. Life cycle assessment based tools for the modeling of development of integrated waste management strategies for cities and regions with rapidly growing economies. Conference Proc. Technical, Economical and organizing aspects of waste management. Poznan-Gniezno, Poland, May 18–21, 2003. 9. Dudek, M., L. Wolska, and J. Namiesnik. 2005. Assessment of the life cycle—multiphase analysis of the product impact on environment. Ecol. Tech. 13: 66–75. 10. Dudek, M., L. Wolska, H. Walk, A. Stachowiak-Wencek, and J. Namiesnik. 2004. Studies on evaluation of the ship lifetime cycle. Ecol. Tech. 15: 141–153. 11. Stoklosa, M. 2006. The use of life cycle assessment (LCA) for ecological comparison of isolation protocols of organic compounds from aquatic samples (in Polish). MSc thesis, Gdansk University of Technology. 12. Goedekop, M., and R. Spriensma. 2000. The Eco-Indicator 99: A damage oriented method for life-cycle impact assessment. Methodology Report 2000a. Available at www.pre.nl. 13. Ekvall, T., and B.P. Weidema. 2004. LCA methodology, system boundaries and input data in consequential life cycle inventory analysis. Int. J. LCA 9: 161–171. 14. Jolliet, O., M. Margni, R. Charles, S. Humbert, J. Payet, and G. Rebitzer. 2003. IMPACT 2002+: A new life cycle impact assessment methodology. Int. J. LCA 8: 324–330. 15. Cooper, J., and J. Fava. 2006. The life cycle assessment practitioners survey: Assessment methods for evolutionary and revolutionary electronic products. Proceedings of the 2006 IEEE International Symposium on Electronics and the Environment, pp. 1–5. 16. Capello, C., U. Fischer, and K. Hungerbühler. 2007. What is a green solvent? A comprehensive framework for the environment assessment of solvents. Green Chem. 9: 927–934. 17. Capello, C., S. Hellweg, C. Seyler, and K. Hungerbühler. 2005. Ecosolvent: A tool for waste-solvent management in the chemical industry. 27th LCA Discussion Forum (17th November). Swiss Federal Institute of Technology. 18. Seyler, C. 2005. Waste-solvent incineration plant. J. Clean. Prod. 13: 1211–1224. 19. Capello, C., S. Helleweg, B. Badertscher, and K. Hungerbühler. 2005. Life cycle inventory of waste solvent distillation: Statistical analysis of empirical data. Environ. Sci. Technol. 39: 5885–5892. 20. Seyler, C., T. Hofstetter, and K. Hungerbühler. 2005. Life cycle inventory for thermal treatment of waste solvent from chemical industry: A multi—input allocation model. J. Clean. Prod. 13: 1211–1224.

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21. Seyler, C., S. Helleweg, S. Monteil, and K. Hungerbühler. 2004. Life cycle inventory for waste solvent as fuel substitute in the cement industry: a multi-input allocation model. Int. J. LCA. 10: 120–130. 22. Seyler, C., C. Capello, S. Hellweg, et al. 2006. Waste-solvent management as an element of Green Chemistry. Ind. Eng. Chem. Rev. 45: 7700–7709. 23. Curzons, A., C. Constable, and V. Cunningham. 1999. A guide to the integration of environmental, health and safety criteria into the selection of solvents. Clean Prod. Process. 1: 82–90. 24. Curran, P., J. Maul, P. Ostrowski, G. Ublacker, and B. Linclau. 1999. Benzotrifluoride and derivatives: Useful solvents for organic synthesis and fluorous synthesis. Topics in Current Chemistry 206: 79–105. 25. Gani, R., C. Jimenez-Gonzales, A. Kate, et al. 2006. A modern approach to solvent selection. Chem. Ing. 1: 30–43. 26. Sawaiko, B. 2004. A promising future for ethanol. World Ethanol Biofuels Rep. 2: 20–28. 27. Thomas, P.G. 2000. An approach to dynamic environmental life-cycle assessment by evaluating structural economic sequences. Dissertation, Tufts University. 28. ISO International Standard 14041, 1999E. Environmental management—life cycle assessment—goal and scope, definition and inventory analysis. International Organization for Standardization (ISO), Geneva. 29. Bennet, R.M., R.H. Phipps, and A.M. Strange. 2006. The use of life cycle assessment to compare the environmental impact of production and feeding of conventional and genetically modified maize for broiler production in Argentina. J. Anim. Feed Sci. 15: 71–82. 30. Steen, B. 1999. A systematic approach priority strategies in product development (EPS). Version 2000. Center for Environmental Assessment of Products and Materials System. Chalmers University of Technology, Technical Environmental Planning, Göteborg. 31. Capello, C., S. Hellweg, and K. Hungerbühler. 2007. Environmental assessment of waste-solvent treatment options: Part I: The ecosolvent tool. J. Ind. Ecol. 11: 26–38. (The Ecosolvent Tool, ETH Zurich, Safety & Environmental Technology Group, Zurich, http://www.sust-chem.ethz/tools/ecosolvent.) 32. Slater, C. and J. Savelski. 2007. A method to characterize the greenness of solvents used in pharmaceutical manufacture. J. Environ. Sci. Health 42: 1595–1605. 33. Jimenez-Gonzalez, C., A. Curzons, and V. Cunningham. 2004. Expanding GSK’s solvent selection guideapplication of life cycle assessment to enhance solvent selections. J. Clean. Tech. Environ. Policy 7: 42–50. 34. Noyori, R. 1999. Supercritical fluids: Introduction. Chem. Rev. 99: 353–354. 35. Leveque, J. and G. Cravatto. 2006. Microwaves power ultrasound, and ionic liquids. A new synergy in green organic synthesis. Chimia 60: 313–320. 36. Sugiyama, H., U. Fischer, and K. Hungerbühler. What is a green solvent? The EHS Tool, ETH Zurich, Safety & Environmental Technology Group, Zurich. Available at http://www.sust-chem.ethz/tools/EHS. 37. Dones, R., T. Heck, and M. Faist Emmenegger. 2004. Final Reports Ecoinvent 2000, No. 1-15, CD-ROM, Swiss Centre for Life Cycle Inventories, Dubendorf, CH. Available at www.ecoinvent.ch. 38. Owens, J.W. 1996. LCA impact assessment—case study using a consumer product. Int. J. LCA 1: 209–217. 39. Owens, J.W. 1997. Life cycle assessment: Constraints on moving from inventory to impact assessment. J. Ind. Ecol. 1: 37–49. 40. Belpoggi, F., M. Soffritti, and C. Maltoni. 1998. Pathological characterization of testicular tumours and lymphomas-leukemias, and of their precursors observed in Sprague-Dawley rats exposed to methyltertiary-butyl-ether (MTBE). Eur. J. Oncol. 3: 201–206. 41. Thomas, P.G. 2000. An approach to environmental life-cycle assessment by evaluating structural economic sequences. PhD dissertation, Tufts University. 42. Bird, M., H. Burleigh-Flayer, J. Chun, and J. Douglas. 1997. Oncogenicity studies of inhaled methyl tertiary butyl ether (MTBE) in CD-1 mice and F-344 rats. J. Appl. Toxicol. 17: S45–S55. 43. Raynolds, M., D. Checkel, and R. Fraser. 1998. Life cycle value assessment (LCVA). Comparison of conventional gasoline and reformulated gasoline. Design and manufacture for environment. SAE International Papers. Doc. No. 980468, SP-1342: 111–130. 44. Peereboom, E., R. Kleijn, S. Lemkowitz, et al. 1998. Influence of inventory data sets on life-cycle assessment results: A case study on PVC. J. Ind. Ecol. 2: 109–130.

19

Preparation of Samples for Analysis: The Key to Analytical Success Jacek Namies´nik and Piotr Szefer

CONTENTS 19.1 19.2 19.3

Introduction .................................................................................................................... Types of Analytical Data ................................................................................................ Speciation Analytics: An Important Task for Analytical Chemists ............................... 19.3.1 Physical Speciation ........................................................................................... 19.3.2 Chemical Speciation ......................................................................................... 19.4 Problems Associated with Trace Element Analysis ....................................................... 19.5 Stages of the Analytical Procedure ................................................................................ 19.6 New Methodological Developments in Preparing Samples for Analysis ....................... 19.7 Application of Membrane Techniques ............................................................................ 19.7.1 Membrane Extraction ........................................................................................ 19.8 Matrix Solid-Phase Dispersion ....................................................................................... 19.9 Supercritical Fluid Extraction ......................................................................................... 19.10 Unique Phase Separation Behavior of Surfactant Micelles ............................................ 19.11 Ionic Liquids: A New Type of Solvent and Extractant ................................................... 19.12 Microwave-Enhanced Chemistry (MEC) ....................................................................... 19.13 Application of Ultrasound (US) in the Sample Preparation Process .............................. 19.14 Green Chemistry: Introduction of the Concept of Sustainable Development to Chemical Laboratories ............................................................................................... 19.14.1 History ............................................................................................................... 19.14.2 Green Analytical Chemistry ............................................................................. 19.15 Summary and Conclusion ............................................................................................... References ..................................................................................................................................

19.1

431 434 435 437 437 439 440 442 442 445 448 449 451 452 454 455 458 458 459 463 463

INTRODUCTION

Recent decades have witnessed a sharply growing demand for information. This also pertains to information obtainable from the analytical examination of samples of material objects. The desire to satisfy the need for analytical data stimulates actions toward • Developing new analytical methodologies • Designing and implementing new technical solutions for the measuring instruments used in analytical practice 431

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Analytical methodologies and measuring instruments are the tools for obtaining reliable data on the composition of the material objects being studied. The science of the construction and operating rules of measuring instruments is often referred to as instrumentation. The successive stages in the development of this science are easily discernible. Access to a variety of information sources facilitates decision-making not only in politics, but also in economy and in technology (related to control over the processes of manufacturing consumer goods). A new type of market has emerged in which information is bought and sold.1 Analytical data on the material objects in question are a specific kind of information, which is based on the analysis not so much of the whole objects as of representative samples of such objects. Samples therefore have to be collected in such a way that the most important criterion— representativeness—is met. To satisfy the growing demand for analytical data, more and more intensive research is taking place with the aim of developing new methodological and instrumental solutions so that analytical results can be a copious source of information; in other words, they can possess the greatest possible information capacity. Measurement results must be reliable (credible), that is to say, they must accurately (both precisely and truly) reflect the real content (amount) of analytes in a sample that is representative of the material object under study. This leads to the conclusion that all developments in analytical chemistry are derived from the desire to obtain in-depth analytical data. Analytical chemistry uses a very broad spectrum of measurement methods and techniques: Table 19.1 presents a basic classification. Depending on the objective of the measurement, one of two fundamental procedures has to be selected. The first is the classical procedure recommended and even required by the official

TABLE 19.1 The Basic Classification of Modern Chemical Analytical Methods Basis for Categorization

Types of Analytical Methods

Comments

1

2

3

Primary methods Relationship methods Secondary methods

Used for direct measurement of units in the SI system Isotope dilution mass spectrometry (IDMS)

Absolute methods

Based on such units as mass, volume, time, and electric current intensity, which do not require calibration By comparing signals from analytes in the model sample and in the examined sample; the calibration stage is necessary An appropriate measurement device (sensor) is inserted into the examined object in order to obtain analytical data (measurement of pH and electrical conductivity) In most cases used because of • Very low analyte concentration levels • The complicated matrix composition and the presence of INTERFERENTS; the sample must be prepared properly, and the analyte concentration is measured in an appropriate extract

Relation to the current international system of units (SI) (location in the comparison chain ensuring traceability) Measurement principle

Relative methods

Direct methods

Means of examining the sample

Indirect methods

continued

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Preparation of Samples for Analysis: The Key to Analytical Success

TABLE 19.1

(continued)

Basis for Categorization

Types of Analytical Methods

Comments

1

2

3

Type of analytical data

Location of the analytical process Means of obtaining analytical data

Means of taking a representative sample

Methods for determining the instantaneous concentration of analytes in the examined material object Methods for determining timeweighted concentrations while taking the sample Methods of making in situ measurements Laboratory methods Methods using devices that can read the amount/concentration of analyte directly Methods with previously prepared samples and the amount/ concentration of analyte calculated from laboratory measurements Sedimentation methods Isolation methods Aspiration methods

Level of automation

Manual methods

Automatic methods

Monitoring methods

Methods used in examining the quality of the environment and determining individual exposure

Appropriate mobile laboratories, movable or portable measurement devices are used Usually used in field research in order to obtain analytical data (often semiquantitative) quickly

Analyte sample is collected by free migration of the analyte onto the collecting surface The sample is put into a container (probe) of specified volume Analyte samples are collected by running a stream of medium through a trap (e.g., a sorption tube) Most of the operations and actions (both in the field and in the laboratory) connected with sample preparation are performed manually All or part of the operations are performed without the participation (intervention) of an operator (analyst) Specific type of automatic methods; the devices used must have the following features: • They must be able to obtain data in real time or with only a slight time delay • They must be capable of performing continuous measurements • They must be able to operate autonomously for extended periods of time

regulations applying to environmental programs. Based on sampling and laboratory analysis, it involves a number of steps between sampling and analysis, such as conditioning, storage, transportation, and pretreatment. The other procedure, carried out on-site, makes use of on-line measurement systems, field-portable devices, or test kits. In actual fact, the two approaches are often used in tandem, combining as they do the scientific relevance of certain practices (e.g., on-site measurement of dissolved gases and temperature) and the availability of systems for on-line monitoring.2 The problem of preparing samples for analysis has been presented in a large number of both original and review papers.3–29 These discuss universal problems in chemical analytics, the problems and challenges concerning the most appropriate ways of preparing material samples for analysis, and the concrete requirements regarding the preparation of samples to be analyzed using a specific technique.30,31

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It must be borne in mind, however, that • Despite further development in instrumentation and the availability on the market of many complex hyphenated devices, the basic principle that a device is merely a necessary and useful tool in the process of obtaining analytical data is often forgotten. Possession of the tool itself will not solve any analytical problems. Without an understanding of the chemistry of the analytical process, no reliable and credible results can be obtained. People who treat an analytical device as a typical black box deserve to be called “operators of analytical devices” rather than “analytical chemists.” In such a situation, erroneous analytical information is all too easily produced, notwithstanding the amount of time and work expended on the analytical process. • There is a need to educate specialists who will be able to make use of these innovative methodologies and devices. Analytical research draws on various procedures and analytical techniques. Some of the measurement devices used are referred to as “monitors” and should have the following operating parameters: • High measurement sensitivity. • Immediate, or at worst only slightly delayed, delivery of analytical information on the investigated object. • High resolution of results characterized by a short response time. • Long period of unsupervised operation. Monitoring also imposes several requirements regarding • • • • •

Instrument zeroing and calibration. Protecting the instrument against power surges. Providing the instrument with an independent power supply. Automatic replenishment with solution and reagents (electrochemical monitors). Installation of devices preventing the flame from going out (in certain detectors, e.g., flame ionization detector (FID) and flame photometric detector (FPD). • Exchange and regeneration of spent filters.

19.2

TYPES OF ANALYTICAL DATA

Data obtained through analysis of samples may prove useful in different fields of science, technology, and human life. They play a particularly vital role when it is necessary to • Describe the condition of the examined material object and discover the changes it is subject to. • Confirm a new theory or scientific hypothesis. • Take a decision concerning the law and the economy. • Plan and implement educational campaigns in order to raise social awareness. Various types of data may be obtained as a result of sample analysis. There is no doubt, however, that in the majority of cases quantitative data (the amount or concentration of analyte in a sample) are most important. It is therefore worth learning the basic terminology of chemical metrology with reference to the quantitative determination of analytes. The diagram in Figure 19.1 will help put these terms in the correct order on the analyte concentration axis [expressed in the same units as the standard deviation of analytical noise (d)].

435

Range

Standard deviation of noise ratio(d)

Preparation of Samples for Analysis: The Key to Analytical Success

10

Qualitative analysis uncertainty

Analyte concentration

Detection certainty

Range

Linearity

HIGH certainty of qualitative analysis

LOL

LOQ MDL RDL

0 Detection uncertainty

LOD

3 HIGH uncertainty of analyte detection

Noise level

0

LOD–Limit of Detection RDL–Reliable Limit of Detection MDL–Method Detection Limit LOQ–Limit of Quantitaion LOL–Limit of Linearity

FIGURE 19.1

Basic metrological terminology relating to the quantitative analytics of trace elements.

Many elements and compounds occur in a variety of matrices at concentrations that could not be detected by the analytical methods first developed in the nineteenth century. As analytical technology improved, and it became known that elements were present at these very low concentrations, the term “trace” was coined to describe them. Although modern analytical methods permit the accurate, repeatable determination of elements at such low levels, the generic terms “trace” and “trace element” are still in use. The boundaries of trace analysis are described by the definition of “trace element” in the IUPAC Compendium of Chemical Terminology, 2nd edition: “Any element having an average concentration of less than about 100 parts per million atoms and less than 100 μg g-1.” As analytical techniques have become more sophisticated and detection capabilities have improved, this upper boundary of the definition of “trace” is now so far away from the capabilities of analysis in a number of fields that new terms such as “ultratrace analysis” have entered common parlance. There is no agreement, however, on the range of ultratrace analysis, and this term has no rigorous definition. In the literature, the term is used to define the presence of elements at mass fractions less than 10 –6 and 10 –8 (1 mg g-1 and 0.01 mg g-1).

19.3 SPECIATION ANALYTICS: AN IMPORTANT TASK FOR ANALYTICAL CHEMISTS Attempts at environmental or health protection can yield only dubious results, if any, if they are based on suspect data. Therefore, a rigid quality control program is required for speciation analysis. Species alterations have to be avoided or minimized; information on the degree of possible species changes must therefore be elucidated.32–39

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In general, there are at least three approaches to the use of the term “speciation analytics” in the analytical context: • Local concentration differences of a particular element or compound in a given structure of a material • The physical distribution of an element or compound in different phases that are in contact with each other • The presence of different chemical conditions or binding states of a particular element within a single phase Initially, speciation analytics was associated only with the biogeochemical cycles of metals in aquatic environments. Even in the 1950s, geochemistry distinguished between two forms that metals could assume: • Metals in dissolved form • Metals bound to suspended matter At that time, passing samples of water through a filter with 45 μm diameter pores was sufficient to properly separate the two phases. Later, following the development of electrochemical analytical methods, it was possible to identify different forms that metals assumed in a dissolved state—free metal ions and complex ion forms. Simultaneously conducted simulation studies on the possible equilibria between ions and organic or nonorganic ligands have led to the conclusion that a wide variety of chemical compounds and metals can exist in aquatic environments. Nowadays, speciation analytics deals not only with metals, but also with other elements and different types of tests. It is well known that the toxicity of many elements depends on the physicochemical forms they assume. So, for instance, determining the total content of a certain element in a sample is definitely not sufficient to measure its toxicity. Selenium is a case in point: in small amounts this element is essential to human health. But the transition from the necessary amount (about 70 μg of selenium per day for an adult) to a toxic dose (about 800 μg of selenium per day) is relatively easy. In rats, moreover, the fatal dose of Se(IV) compounds is 3.2 mg kg-1 of body mass, whereas for dimethyl selenide it is 1600 mg kg-1 of body mass. Nonorganic selenium compounds [Se(IV) and Se(VI)] are believed to be the most toxic ones, whereas in the environment selenium occurs most commonly bound to amino acids (selenomethionine and selenocysteine). The least toxic forms seem to be the volatile methyl compounds of selenium, which are metabolites of a detoxication process. The question concerning what “speciation” actually means is very often asked: the answer can be found in IUPAC recommendations. Table 19.2 presents the most frequently used terms. Generally speaking, speciation analytics plays a very important role in • • • • • • •

Studies of the geochemical cycles of elements and chemical compounds Determining the toxicity and ecotoxicity of given compounds The quality control of food products Research into the environmental impact of technological installations The examination of occupational exposure The control of medicines and pharmaceutical products Clinical analysis

Different chemical species and their physical forms behave differently in geochemical, ecological, and metabolic cycles. This applies in particular to • Deposition • Accumulation

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TABLE 19.2 Terms Connected with Speciation Analytics Term

Definition

Chemical (species) Speciation Speciation analysis Fractionation

• • • • • •

Specific form of an element defined according to isotopic composition, electronic or oxidation state, and/or complex or molecular structure Distribution of an element among its chemical species in a system Analytical activities of identifying and/or measuring the quantities of one or more individual species in a sample Classification process of an analyte or a group of analytes from a certain sample according to physical size/solubility or chemical properties (bonding and reactivity)

Mobility/transportation Phase transfer (Re)mobilization (Bio)availability Resorption/excretion Essentiality/toxicity.

The physicochemical properties of particular species strongly influence their behavior in complex multiphase systems such as specific ecosystems. Special attention should be paid to • • • • • •

Solubility Æ mobility, remobilization, resorption, deposition Volatility Æ phase transfer, transportation Oxidation state Æ bioavailability, essentiality, toxicity Reactivity Æ remobilization, bioavailability Polarity/charge Æ accumulation, bioavailability Molecular weight Æ mobility, phase transfer, deposition

A search of the literature reveals that several types of speciation analytics can be distinguished (see below).

19.3.1

PHYSICAL SPECIATION

Physical speciation takes place when different forms of the same chemical species have to be determined in a sample. Examples include adsorbed forms, dissolved forms, complex forms, and so on.

19.3.2 CHEMICAL SPECIATION Chemical speciation occurs when different chemical species should be determined in the sample under investigation. It is possible to distinguish five types of chemical speciation: • Screening speciation—the detection and determination of one particular analyte, for example, one known for its especially high environmental toxicity • Group speciation—determination of the concentration level of a specific group of compounds or of elements existing in different compounds in a specific oxidation state, and their physical forms

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• Distribution speciation—this takes place when the same chemical species needs to be determined in different compartments of the material object under investigation • Chiral speciation—determination of the enantiomers of the given compound • Individual speciation—the most difficult type encountered in speciation analytics, involving the broadest range of analytical work. Its purpose is to separate, detect, determine, and identify all species of an element in a sample. Specialists in speciation analytics are interested in various chemical species and the physical forms that certain elements assume. Here are some examples of the physicochemical forms of trace element species in water bodies: Dissolved

• • • • •

Simple hydrated ions Inorganic complexes Organic complexes Molecules and polymeric compounds Ion pairs

Colloidal

• Mineral substances • Products of hydrolysis and precipitation • Biopolymers

Suspended particles

• • • •

Mineral substances Precipitates and agglomerated colloids Plankton Bacteria and microorganisms

A set of important factors affects the formation, stability, and transformation of dissolved elemental species in the samples under investigation, namely, • • • • •

Shift of pH Change of redox potential Presence of reactants (e.g., inorganic and organic ligands) Catalytic effects Presence of particulate matter and microorganisms (adsorption and biotransformation).

Speciation analysis comes into its own mainly in environmental, nutritional, and biomedical research. The sample matrices are generally highly complex and the requirements for reliable (trace) element determinations are stringent (even for total amounts). The most important challenges in this context involve • • • • • • •

The often very low concentration of an individual species Large concentration differences between the elemental species Small structural differences in the elemental species The low thermodynamic and kinetic stability of a species Preserving the integrity of the sought-after species throughout the analytical procedure The existence of as yet unidentified species The nonavailability of suitable reference materials

Certain specific analytical methodologies are available for speciation analytics. The most common of them are • Direct in situ detection of species (e.g., ion selective electrodes and electron spectrometry) • Chemical derivatization of individual species (optical molecular spectrometry)

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439

• Separation of individual species and element-specific detection (extraction, sorption, ion exchange, gas permeation, and electrolysis) • Separation of all species and their determination (chromatographic and electrophoretic methods) Chromatographic techniques are the techniques of choice for speciation analytics. In specific cases, however, nonchromatographic techniques may need to be applied in view of the characteristic properties of the analytes. They are as follows: • Differentiation of oxidation states of inorganic metal compounds • Electrochemical methods • Selective derivatization and molecular spectrometry • Ion-exchange separation of anionic and cationic species • Separation of inorganic ions from organic species • Solvent extraction • Solid-phase extraction (SPE) using reversed-phase materials • Separation of volatiles from nonvolatiles • (Isothermal) distillation • Dynamic headspace analysis (purge-and-trap) • Separation of low- and high-molecular-weight compounds • Membrane techniques (dialysis, ultrafiltration) Speciation is one of the forces driving development in the field of chemical analytics and instrumentation, and the following novel approaches in this field have come into use: • High-resolution separation techniques in hyphenation with high-sensitivity detectors (two-dimensional separations) • Separation techniques in hyphenation with elucidation of the structure of organometallic compounds [electrospray ionization-mass spectrometry (ESI-MS) and matrix assisted laser desorption ionization-mass spectrometry (MALDI-MS)] • New in situ techniques with enhancements in sensitivity and selectivity (sensors based on molecular imprinted polymers) • Selective sampling for species, making use of “biological receptors” • (New) reference materials and round robin tests for quality control

19.4

PROBLEMS ASSOCIATED WITH TRACE ELEMENT ANALYSIS

Many analysts are faced with the problem of determining the content of trace and microtrace components in samples with complex and often varying matrix compositions. There is no doubt that this kind of analytical work poses a special challenge. The end result of analysis is influenced by a number of additional factors, which are not taken into account when the presence of higher content components is determined (these issues have been discussed in a great many publications).40–52 But the lack of awareness of these specific requirements when performing analytical research on various types of samples for trace elements may lead to situations where the obtained result, instead of being a reliable source of analytical data, will supply erroneous information. Contamination of the sample with the analyte and/or losses of the analyte from the sample are the most important systematic errors that can occur during preparatory steps such as53 • Sampling • Storage • Sample pretreatment

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Analytical Measurements in Aquatic Environments

• Separation of constituents • Final determination. The first steps of an analytical procedure have been a largely neglected area in trace analysis for a long time, research having been focused mainly on improving the sensitivity and selectivity of the procedure. But over the last 20 years, analysts have come to recognize that the majority of systematic errors may be introduced at the very beginning rather than toward the end of a combined analytical procedure. A good analytical strategy will also include a sampling procedure free of contamination and losses, as well as proper stabilization and storage of the sample. As analytical chemistry is a discipline that helps other disciplines and solves their problems, close cooperation is clearly necessary. In practice, the analytical chemist is often not involved in the actual sampling procedure; indeed, he/she is mostly not even informed of the sample’s origin. This state of affairs must inevitably give rise to serious systematic errors already in the first steps of an analytical procedure. The influence of contamination and losses on analytical results becomes increasingly important with diminishing analyte concentrations. These effects depend not only on the concentration range, but also on the nature of the analyte. One should bear in mind that while contamination and/or losses can never be completely eliminated, it is imperative that they be reduced to an acceptably low level.

19.5 STAGES OF THE ANALYTICAL PROCEDURE Every analytical procedure is a series of stages that take place in a specific sequence. It can therefore be compared with a chain consisting of a great number of links, where it is obvious that the entire chain is as strong as its weakest link. This is illustrated diagrammatically in Figure 19.2. The final step (interpretation and evaluation of analytical results) should provide the definitive answer to the initial problem, generally stated by a client of the laboratory. If the answer is not satisfactory, the analytical cycle can be repeated, after a change to or adaptation of one or more steps. Sometimes this leads to the development of a new method or the modification of part of the procedure in order, for example, to achieve better separation of certain components or to attain a lower detection limit for specific compounds. Generally speaking, the weakest link in a chain of chemical analysis is not the one usually regarded as a part of such a process, for example, chromatographic separation or spectrometric detection. It is more likely to be one of the preceding steps, often taking place outside the analytical laboratory, such as the selection of object(s) to be sampled, the design of the sampling plan, and the selection and use of techniques and facilities for obtaining, transporting, and storing samples.54 When the analytical laboratory is not responsible for sampling, the quality management system often does not even take these weak links in the analytical process into account. Furthermore, if sample preparation (extraction, cleanup, etc.) has not been carried out carefully, even the most advanced, quality-controlled analytical instruments and sophisticated computer techniques cannot prevent the results of the analysis from being called into question. Finally, unless the interpretation and evaluation of results are underpinned by solid statistical data, the significance of these results is unclear, which in turn greatly undermines their merit. We therefore believe that quality control and quality assurance should involve all the steps of chemical analysis as an integral process, of which the validation of the analytical methods is merely one step, albeit an important one. In laboratory practice, quality criteria should address the rationality of the sampling plan, validation of methods, instruments and laboratory procedures, the reliability of identifications, the accuracy and precision of measured concentrations, and the comparability of laboratory results with relevant information produced earlier or elsewhere. On the basis of a wide range of information, it can be stated that extracting and preparing samples for analysis are the weakest links in this chain. This leads to one very obvious conclusion,

Preparation of Samples for Analysis: The Key to Analytical Success

441

Input

Receiver

Assurance and interpretation of data (analytical results)

Definition of the problem presented by the client

Definition of analytical problem

Selection for the material for sample handling

Data pretreatment and their storage

Strategy and handling techniques

Analysis (separation and detection)

Sample pretreatment

Sample handling

The weakest part of the chain

FIGURE 19.2 Graphical representation of the analytical procedure in the form of a chain—the links are the particular stages and operations.

namely, that it is necessary to pay particular attention to these two stages so that the outlay of time, labor, and money produces the desired effect, that is, reliable analytical data, for which there is a great demand. The extracted samples must be appropriately prepared for the final stage of analysis. The various operations performed in situ and/or in the laboratory yield a sample for analysis that is characterized by appropriate values of the following parameters: • • • •

Size (mass, volume) State of matter Analyte concentration range Presence of interferants.

Figure 19.3 shows the contribution of different parts of analytical procedures to the whole uncertainty budget and the duration of analysis. The information used for preparing these diagrams was collected in a questionnaire sent to over 250 respondents (analytical laboratories in Central European countries). Keeping documentation up-to-date is also a significant aspect of the sample preparation stage.55 Chromatographic and related techniques play a vital role in chemical analytics. They should be regarded as a tool with a very high decomposition potential. Appropriately prepared samples for analysis may still extend the practical range of applications for chromatographic techniques. In analytical practice, analytes in organic samples, the matrix compositions of which are often very complex and variable, are isolated and enriched using a wide spectrum of techniques based on the mass transport phenomenon.56,57

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Analytical Measurements in Aquatic Environments Error sources Data processing 10%

Measurement and calibration30%

Analysis duration Data processing 27% Sampling and sample preparation Measurement 60% and calibration; 8%

Sampling and sample preparation; 67%

FIGURE 19.3 Contribution of different parts of analytical procedures to the whole uncertainty budget and the duration of analysis.

19.6

NEW METHODOLOGICAL DEVELOPMENTS IN PREPARING SAMPLES FOR ANALYSIS

Table 19.3 compares published information on new methodological solutions for preparing samples with complex matrices for final determinations.

19.7 APPLICATION OF MEMBRANE TECHNIQUES Expressed simply, a membrane can be treated as a selective barrier between two phases. The phase in which mass transfer takes place is called the donor phase, the other phase being called the acceptor

TABLE 19.3 General Information on New Methodological Developments in Preparing Samples for Analysis Innovatory Examples (New Solutions)

Operations Related to the Sample Preparation Stage

1

2

3

1.

Cloud point phenomenon (cloud point extraction—CPE) Pressure-assisted chelating extraction (PACE) Sequential solid-phase extraction (SSPE) Development of matrix solid-phase dispersion (MSPD) concerning: • New sorbents • Temperature and pressure of extraction • Cleanup of extracts • Miniaturization Application of pressurized hot water (subcritical water) as the extraction medium

No.

2. 3. 4.

5.

Reference 4

Extracting analytes (both organic and inorganic) from water samples

58–65

Novel technique for the digestion of metals in solid matrices

66

Extraction of nonsulfonic acids from coastal water samples

67–69

Extraction of organic xenobiotics from a variety of solid, semisolid, and viscous environmental and biological matrices

70–75

• Extraction of moderately and nonvolatile, thermally stable 76–78,79 organic pollutants from a variety of solid and semisolid environmental matrices • Extraction of metals such as copper and lead from spent industrial oils with acidified pressurized hot water extraction (PHWE) continued

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Preparation of Samples for Analysis: The Key to Analytical Success

TABLE 19.3

(continued)

Innovatory Examples (New Solutions)

Operations Related to the Sample Preparation Stage

Reference

1

2

3

4

6.

New achievements and development of new techniques: pressurized liquid extraction, PLE; accelerated solvent extraction, ASE; pressurized fluid extraction, PFE) Microemulsion-mediated in situ derivatization— extraction (INDEX)

No.

7.

8.

9.

10. 11.

12.

13.

Extraction of different microcontaminants from a variety of semisolid samples

77,80–85

Derivatization—extraction of acidic compounds in a water matrix with alkylbromides in a homogenous reaction mixture produced by mixing water, hydrophilic alkyl bromide, and cosolvent Derivatization of phenolic acid in water prior to its chromatographic determination

86

Enzyme catalyzed esterification of phenolic acids in a surfactantless microemulsion system (SLME) Application of ultraviolet Postcolumn UV irradiation to destroy the structure of organic (UV) radiation at different compounds leaving the chromatographic column stages of sample preparation Oxidizing organic matter contained in the sample Hybrid photocatalysis/membrane treatment of water UV digestion of the sample New achievements in wet Sample matrix digestion with the use of chemical reagents digestion techniques New applications of In situ derivatization reactions prior to SFE with CO2 supercritical fluids Sequential supercritical fluid extraction (SSFE) for estimating the availability of PAHs in a solid Supercritical water oxidation technology (SCWO) applied to the treatment of industrial wastes and sludges Application of ultrasound Ultrasonic treatment of wastes and waste-activated sludges (US) (sonochemistry) New US-assisted extraction techniques for both inorganic and organic sample constituents under investigation US-assisted cold vapor generation Focused sonic probe for speciation analytics Mineralization of organic compounds by a heterogeneous US/ catalyst process Ultrasonic atomization applied to the removal of endocrine disrupting compounds (EDCs) from an aquatic environment Sono-sorption as a new technique for removing lead ions from an aqueous solution UV disinfection of water Miniaturization of extraction Single-drop extraction of different types of analytes from liquid with a solvent and gaseous matrices Liquid–liquid microextraction of organic micropollutants from water

87

88 77,89 90 91 91–95 96 97 98 99,100 31,34,101–109 110 108 111,112 113 114 115 116–123 124,125

continued

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TABLE 19.3 No. 1 14.

15.

16.

(continued)

Innovatory Examples (New Solutions)

Operations Related to the Sample Preparation Stage

Reference

2

3

4

Application of new types of membrane-based devices as suitable techniques for the extraction of a broad spectrum of analytes from various matrices

Application of semipermeable membrane devices for evaluating persistent organic pollutant (POP) bioavailability in water Permeable environmental leaching capsules (PELCAPs) for in situ evaluation of contaminant immobilization in soil Application of cellulose membrane and chelator to differentiate labile and inert metal species in aquatic systems Supported liquid hollow fiber membrane microextraction of analytes from water samples New type of heated membrane introduction mass spectrometry interface New achievements in the application of permeation liquid membranes (PLMs) Application of different types of filtration to evaluate the distribution of size-fractionated particulate matter Chromatomembrane cells as a unit for advanced sample pretreatment in the monitoring of different types of organic compounds in water Optimization of different derivatization approaches for determining pentachlorophenol (PCP) in wastewater irrigated soil Application of ion-pair extraction and derivatization of analytes from groups of aliphatic and aromatic amines in various environmental matrices prior to gas chromatography-mass spectrometer (GC-MS) determination Solid-phase microextraction (SPME) for sampling analytes from different matrices and introducing them to the analytical device Application of stir bar sorptive extraction (SBSE) in environmental analytics Miniaturization and automation of SPE devices Validation of the fluidized-bed extraction (FBE) technique for determining POPs in solid samples Molecularly imprinted polymers for extracting organic compounds from environmental and biological samples Development and characterization of an immunoaffinity SPE sorbent for trace analysis Extraction syringe—a device connecting sample preparation and GC Evaluation of multiwalled carbon nanotubes as an adsorbent for trapping volatile organic compounds (VOCs) from environmental samples Studies of extraction techniques based on the application of polydimethylsiloxane (PDMS) as a trapping medium Hemicelle- and admicelle-based SPE of linear alkylbenzene sulfonates (LASs) and phthalate esters from water Colorimetric solid-phase extraction (CSPE) in speciation analytics New extraction materials used for isolating analytes from complex samples and cleaning up extracts • Polymeric materials • Inorganic sorbents • Natural sorbents

Derivatization of analytes with new agents

New applications of the SPE technique

126 127 128 129–134 135 136,137 138–142 143

144 145

102,146–155 156–162 163–167 63,168 169–176 177 178,179 180–182

183–185 186,187 188

189–200 201,202–205 17,201,202, 205,206

Preparation of Samples for Analysis: The Key to Analytical Success Donor phase (water+analytes)

Membrane

445

Acceptor phase (solvent)

Driving force in the process

FIGURE 19.4

Schematic representation of transport across membranes.

phase.56 The general principle for separating liquid mixture components using membranes is shown schematically in Figure 19.4. The main factors affecting mass transfer across a membrane are • The type of membrane • The force driving the extraction process A number of criteria are used for classifying membranes. The ones most often taken into account are56 • The state of the membrane • The morphology of the membrane (closely related to porosity and internal structure) • The shape of the membrane Figure 19.5 shows a diagram illustrating membranes classified according to the above criteria, and Table 19.4 summarizes information on the morphology of various types of membranes that could find application in environmental analytical chemistry. The separation of components in the membrane process is due to differences in the transfer rate of chemical compounds across the barrier. It is a nonequilibrium process, in which the flow of a component depends on the driving force. Table 19.5 provides some basic information on the forces driving membrane processes. Various analytical techniques make use of both porous and nonporous (semipermeable) membranes. For porous membranes, components are separated as a result of a sieving effect (size exclusion), that is, the membrane is permeable to molecules with diameters smaller than the membrane pore diameter. The selectivity of such a membrane is thus dependent on its pore diameter. The operation of nonporous membranes is based on differences in solubility and the diffusion coefficients of individual analytes in the membrane material. A porous membrane impregnated with a liquid or a membrane made of a monolithic material, such as silicone rubber, can be used as nonporous membranes.

19.7.1

MEMBRANE EXTRACTION

The membrane extraction process mostly makes use of nonporous membranes. Such a membrane can be a liquid or a solid phase (a polymer impregnated with a liquid), which is placed between two

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Analytical Measurements in Aquatic Environments

Membranes

State

Shape

Morphology

Solid

Porous

Planar

Nonporous

Liquid

Symmetric

Tapes

Two phases

Asymmetric

Sheets

Gel

Composite

Tubes

Dynamic

Capillary Hollow fibers

FIGURE 19.5

Classification of membranes with respect to their state, morphology, and shape.

TABLE 19.4 Information on Membrane Morphology Porous Membranes Symmetric • Capillary or irregular pores • Identical porosity perpendicular to external surfaces • Preparation methods: • Sintering • Radiation with etching • Phase inversion

Asymmetric • • • • •

•

•

•

Increase in porosity perpendicular to the surface Smallest porosity in the surface layer Separation layer—surface layer Support layer (reinforcing) • The rest of the membrane Methods of formation: • Thermal gelation • Vapor adsorption • Loeb–Sourirajan phase inversion Composite asymmetric membranes: • Two- or multilayer • Different composition of individual layers • Formed by coating a layer of selective properties onto a porous protective layer Dynamic asymmetric membranes: • Formed dynamically • Formed by coating colloids or macromolecular compounds onto a porous bed under pressure Support—filtration foil made from an organic material; plate, tube, or molder made from a ceramic, carbon, or metal sinter continued

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Preparation of Samples for Analysis: The Key to Analytical Success

TABLE 19.4

(continued) Nonporous Membranes

Symmetric

Asymmetric

• Lack of conventional pores (pores of molecular dimensions) • Continual variations in the number, size, and location of pores as a result of thermal molecular motions in the membrane material Solid

Liquid

Inorganic membranes: • Material: metals, metal alloys, sintered ceramics, glass • Organic membranes: • Material: natural and synthetic polymers, for example, cellulose acetate, silicone rubber, polyethylene

• Thin liquid layer with a dissolved mediator • Separates a donor solution from an acceptor solution • Kinds: • Thick layer • Emulsion • Reinforced

Ion-Exchange Membranes • Nonporous, microporous, and porous membranes of symmetric or asymmetric structure • Kinds: • Cationic (cation exchange)—cations pass toward the cathode through a constant electrical field and exclude anions • Anionic (anion exchange)—anions pass toward the anode through a constant electrical field and exclude cations

other phases, usually liquid, but sometimes also gaseous. A review of the available literature indicates that the term “membrane extraction” includes the following types of apparatus and procedures56,207–210: • • • •

Supported liquid membrane extraction (SLM) Microporous membrane liquid–liquid extraction (MMLLE) Polymeric membrane extraction (PME) Membrane extraction with a sorbent interface (MESI).

Table 19.6 gives basic information on these techniques.

TABLE 19.5 Basic Information on the Driving Forces in Membrane Processes Driving Force of the Extraction Process

Name and Mathematical Form of the Equation Used to Describe Mass Transfer

1

Concentration gradient

2

Pressure difference

3

Potential difference

Fick’s law of diffusion: Jm = –DaA(dC/dx) Hagen–Poisseuille equation: Jv = –KbA(dP/dx) Ohm’s law: Jc = –RcA(dE/dx)

No.

a b c d

Diffusion coefficient. Hydrodynamic permeability. Resistance. A, diffusion surface (membrane surface).

Membrane Techniques in which the Mass Transfer Equations are Used Dialysis, membrane extraction Filtration Electrodialysis

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Analytical Measurements in Aquatic Environments

TABLE 19.6 Basic Information on the Membrane Extraction Techniques Applied in the Analysis of Liquid Samples Acronym SLM MMLLE PME MASE MESI

Name of Technique

Type of Membrane

Supported liquid membrane extraction Microporous membrane liquid–liquid extraction Polymeric membrane extraction, Membrane-assisted sorbent extraction

Nonporous Nonporous (microporous)

Membrane extraction with a sorbent interface

Nonporous

Nonporous

Combination of Phases Used: Donor/Membrane/Acceptor Aqueous/organic/aqueous Aqueous/organic/organic Organic/organic/aqueous Aqueous/polymer/aqueous Organic/polymer/aqueous Aqueous/polymer/organic Gaseous/polymer/gaseous Liquid/polymer/gaseous

19.8 MATRIX SOLID-PHASE DISPERSION In 1989, solid sorbents were used for the first time to extract analytes from solid samples. Samples were placed in a glass mortar and blended with modified silica.14 Sorbent was added in order to211 • Grind the sample evenly (the sorbent acts as an abrasive material) • Bind solvents that cause lysis of cellular membranes for biological material • Improve the mechanical properties of the sample blended with sorbent, which makes the fractionated extraction of analytes possible (the mixture of sample and sorbent is a new type of filling) The liquid extraction technique from ground solid samples may be used to isolate analytes from a solid. This extraction method is particularly useful when extracting analytes from dense materials, such as food, plant and animal tissues, or fats. The extraction column with a paper filter at the bottom was filled with the sample prepared as described above. The deposit was secured with a paper filter at the top as well, and the whole was compressed with a special piston. Next, the column was filled with a known volume of solvent for extraction. Solvent flow was forced with a rubber pipette syringe, and the solvent was collected in special receivers. This method of extraction is different from SPE in that for the latter the samples put in the column must be in the form of a liquid solution. The interactions between the various components of the dispersed sample are stronger and to some extent different from those occurring in SPE. Specific interactions among all elements of the system, that is, analytes, interferants, the sample matrix, the solid sorbent added to the sample, and the solvent used for extraction, have been observed. The obtained extracts were purified using SPE or were subjected to final analysis using chromatographic techniques without purification. This extraction technique is similar to classic sample homogenization techniques, which usually involve grinding, pounding, or crushing samples. The effects of mechanical grinding are often enhanced by adding solvents, acids, alkalis, detergents, or chelating agents, which usually leads to the partial extraction of analytes—an unintended effect. The extracted compounds may adsorb on the walls of the vessels and instruments used. Emulsion formation may be another negative effect. In such a case, it is necessary to centrifuge and re-extract analytes from the sample, which is an additional obstacle to carrying out an analytical procedure. Medium pressure liquid extraction (MPLE) is an extraction technique intermediate between MSPD and ASE. In this case, the ground sample mixed with solid sorbent fills the chromatographic column through which the solvent is

Preparation of Samples for Analysis: The Key to Analytical Success

449

pumped by means of a special, low-pressure pump. The column discharge (extract) may be subjected to final analysis without further purification.

19.9 SUPERCRITICAL FLUID EXTRACTION A supercritical fluid is a substance that comes into existence after the so-called critical point has been exceeded, that is, when it simultaneously exhibits the properties of a gas and a liquid, but is actually neither the one nor the other. In 1962, Klesper, Corwin, and Turner were the first researchers to use supercritical fluids for analytical purposes. A supercritical fluid was used in highpressure fluid chromatography, where it was part of the mobile phase. Extraction with a supercritical fluid was first achieved in 1978, since when the supercritical fluid extraction (SFE) technique has been undergoing active development, finding many applications in laboratory analysis and industry.212 On exceeding the critical point, the substance shows certain characteristics of both a gas and a liquid at the same time, but also a number of properties characteristic only of this form of matter, namely, • It does not condense. • It does not boil. • It does not form a meniscus (a characteristic property of liquids), but it does have the capability to dissolve, which is characteristic of liquids. • High “diffusibility”: Dissolved substances spread in a supercritical fluid at speeds between those of liquids and real gases. • No surface tension: A supercritical fluid can thus penetrate even the smallest pores of the sample matrix. • The low viscosity of supercritical fluids ensures effective penetration of the entire sample. This combination of the aforementioned properties of supercritical fluids accounts for the fact that they penetrate the sample matrix like a gas and at the same time dissolve analytes like liquids. Every substance has its own individual critical pressure and temperature that is often difficult to obtain under laboratory conditions. Because of this, and despite attempts to use various substances as extraction media during the development of SFE, most of these substances have proved useless. A substance with favorable critical parameter values and that best matches the other aforementioned criteria is carbon dioxide (CO2). The critical temperature of CO2 is +31.3°C, which is especially important for thermally unstable analytes, and its critical pressure of 72.9 bar (1 bar = 105 Pa) is easy to obtain under laboratory conditions. Moreover, CO2 is nonflammable, nontoxic, does not pose any additional, serious threat to the environment, and is relatively inexpensive. For on-line solutions, it is important that CO2 be compatible with most chromatographic detectors. Because CO2 has weak dissolving capabilities, it is suitable as an extraction medium in SFE only for compounds of small and medium molecular mass and of low polarity. As a result, suitable modifiers must be added in order to extract polar substances. Modifiers are polar organic solvents, that is, with a nonzero dipole moment (methanol, acetonitrile, tetrahydrofuran, or water are the most commonly used) that enhance the diffusibility of polar analytes in nonpolar extraction media such as CO2. SFE is carried out above the solvent critical point, and the properties of a supercritical fluid depend on pressure and change along with its density. These criteria determine the selectivity of the extraction medium. One fluid can therefore be used to extract a whole series of compound groups (depending on the pressure in the system, the temperature, extraction medium volume flow, and extraction time) and to separate the obtained extract into appropriate fractions. Selective fractionation is used, for example, to separate olfactory and gustatory substances in the extraction of hops for beer production.

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Analytical Measurements in Aquatic Environments

Fractions of three groups of substances used in beer production are extracted from hops using supercritical CO2. The first fraction, the so-called oil essence, was obtained via extraction with CO2 at a density of 0.30 g mL-1 and a temperature of 50°C. Bitter substances were collected as the second fraction at a CO2 density of 0.70 g mL -1 (50°C); that fraction overlapped only slightly the third and last fraction of neutral fats, extracted at a CO2 density of 0.90 g mL -1 (50°C). The extraction medium in SFE is supplied from a cylinder to a pump where it is compressed to the desired pressure in the critical range. Next, the fluid in this form reaches the vessel containing a sample situated in a chamber heated to the critical temperature. Here, the substance, already in the supercritical fluid state, extracts the analytes, and the extract is collected in a special receiver. Figure 19.6 shows a diagram of the instruments used for SFE. The sample for extraction is situated in a special container that is then introduced into the chamber. These are the two preparatory stages before sample extraction. For solid samples, an additional homogenization stage is necessary, which facilitates the diffusion of analytes in the whole sample volume. Desiccants, such as Na2SO4 or MgCl2, are often added to a sample in order to remove moisture. Soils and sediments usually contain certain amounts of organosulfur compounds, which decompose under the influence of temperature, and the products of this decomposition may cause fluctuations in flow volume and even choke the outflow from the extraction chamber. To avoid such complications, acid-cleaned copper granules, which react with organosulfur compounds to produce copper sulfide, are placed in the sample-containing chamber. SFE may be carried out in both off-line and on-line systems. In the off-line case, the receiver may be an empty container, a trap, an analytical column with which further analysis will be carried out, or a container with the solvent. There are several variants of SFE in the off-line system: extraction in a dynamic or static system, or in a supercritical fluid recirculating system. Extraction under static conditions consists of flooding the sample with a supercritical fluid, where it is “drenched” for some time, and then the solvent, together with the enriched analytes, is taken to a receiver. The “drenching” stage is useful when the analytes are difficult to isolate from the matrix owing to the low dissolution rate or the compact structure of the sample. In a supercritical fluid

Cooling medium

Extractional cell in furnace

Receivers CO2

Modifier pump

Syringe pump

Modifier a

FIGURE 19.6

Diagram of apparatus used for SFE.

b

c

Preparation of Samples for Analysis: The Key to Analytical Success

451

recirculating system, one dose of solvent is pumped many times through the sample container. After some time, the solvent with the isolated analytes is entirely or partly collected in the receiver. For on-line SFE, the extract in the container is not collected in the container, but is supplied directly to the analytical apparatus. In a dynamic extraction system, the supercritical fluid is pumped only once through the container with the sample to the receiver. In the receiver, the liquid is vaporized, leaving concentrated analytes that are then dissolved in a small volume of the solvent. Such extracts are analyzed to determine selected analytes. This manner of extraction is effective if the analytes are well soluble in the solvent and the sample matrix is penetrable. Apart from the aforementioned possibility of fractionated extraction, SFE has many other advantages accruing from the special properties of supercritical fluids: • Amounts of solvents (usually harmful to the environment and human health) are substantially reduced compared with “classical” extraction methods, such as extraction by shaking or Soxhlet extraction. • Extraction samples are small. • Extraction times are shorter. • The costs of the process are lower compared with “classical” techniques. • Low temperatures are used, which favors the extraction of thermally unstable compounds.

19.10 UNIQUE PHASE SEPARATION BEHAVIOR OF SURFACTANT MICELLES Aqueous solutions of neutral (i.e., nonionic or zwitterionic) surfactants can form micellar assemblies in which a certain number of surfactant molecules aggregate to form an assembly possessing a central core region comprised of long alkyl (or alkylaryl) hydrocarbon chains with their more polar polyethyleneoxide (or zwitterionic) headgroups extending outward and interacting with the bulk water.213 Aqueous solutions of neutral surfactants have two particularly important properties—their solubilizability and phase separation behavior—that can be exploited in order to develop a new viable extraction–preconcentration technique. Firstly, it is well known that micellar aggregates in water can solubilize and bind hydrophobic solute molecules that are typically insoluble or only sparingly soluble in bulk water. For example, although the solubility of pyrene and anthracene in water is in the 0.1–0.6 micromolar range, their solubility can easily be increased to the 10 millimolar range in the presence of micelles. The amount of solute solubilized and bound to the micellar aggregate in an aqueous solution is typically proportional to the surfactant concentration up to the limiting value. In view of its superior solubilizing power, the addition of a known volume of solution containing micellar surfactant to either a given volume of an aqueous solution of a sample or a given mass of a solid sample provides micelles capable of binding and concentrating (in the former) or desorbing and then binding (in the latter) in the micellar entity the organic species that were originally present in the aqueous or solid sample. For the extraction technique for solids, an aqueous concentrated neutral surfactant micellar solution is merely placed in contact with or passed through the solid sample containing the organic component(s). The organic solute(s) present is/are desorbed and solubilized into the micelles in the bulk solution, which are then further enriched (as will be described shortly) by the phase separation behavior of the surfactant solution. The desorption process is thought to be similar to the molecular mechanism reported for the solubilization of water-insoluble solids by micellar solutions, which involves direct micelle diffusion to and from the surfactantmodified solid surface, in series with interfacial steps including adsorption and desorption of the micellar organic species.214–216 A significant advantage of this bulk micellar extraction technique is that once the initial “extraction” from the solid matrix has been performed, the organic component(s) now present in the extractant micellar solution can be further enriched and preconcentrated prior to final quantitation

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Analytical Measurements in Aquatic Environments

of the workup (as can be any organic species originally present in a waterborne sample to which a small amount of a concentrated surfactant micellar solution has been added). This preconcentration is made possible by the phase separation ability of micellar solutions. Aqueous solutions of neutral surfactant micellar compositions can exhibit the so-called critical phenomena and clouding following a change in temperature: Upon increasing the temperature of such isotropic aqueous micellar solutions, a critical temperature is eventually reached at which the aqueous solution suddenly becomes turbid (clouding point) owing to the reduced solubility of the surfactant micelles present in the bulk water. After some time interval (which can be speeded up by centrifugation), separation into two transparent liquid phases occurs (i.e., the formation of a wet surfactant-rich micellar phase in equilibrium with almost pure water containing the same surfactant molecules). Any organic species present that can bind and partition to the micellar entity will be extracted into and thus concentrated in the small volume element of the surfactant-rich micellar phase. A plot of the temperatures required for clouding versus surfactant concentration typically exhibits a minimum in the case of nonionic surfactants (or a maximum in the case of zwitterionics) in its coexistence curve, with the temperature and surfactant concentration at which the minimum (or maximum) occurs being referred to as the critical temperature and concentration, respectively. This type of behavior is also exhibited by other nonionic surfactants, that is, nonionic polymers, n-alkylsulfinylalcohols, hydroxymethyl or ethyl celluloses, dimethylalkylphosphine oxides, or, most commonly, alkyl (or aryl) polyoxyethylene ethers. Likewise, certain zwitterionic surfactant solutions can also exhibit critical behavior in which an upper rather than a lower consolute boundary is present. Previously, metal ions (in the form of metal chelate complexes) were extracted and enriched from aqueous media using such a cloud point extraction approach with nonionic surfactants. Extraction efficiencies in excess of 98% for such metal ion extraction techniques were achieved with enrichment factors in the range of 45–200. In addition to metal ion enrichments, this type of micellar cloud point extraction approach has been reported to be useful for the separation of hydrophobic from hydrophilic proteins, both originally present in an aqueous solution, and also for the preconcentration of the former type of proteins.

19.11 IONIC LIQUIDS: A NEW TYPE OF SOLVENT AND EXTRACTANT Ionic liquids, a new type of solvent, are salts that contain ions (an organic cation and an anion, usually inorganic) and occur as liquids at room temperature. There are three main types of ionic liquids218: • Quaternary ammonium salts [R xNH4-x] +Y• Iminium salts R

R

N

N+ Y–

Y–

N+ R Imidazolium salt

Pyridinium salt

• Phosphonium salts [R xPH4-x] +Y-, where x = 1, 2, 3, 4 and Y = BF4, PF6, NO3, SbF6, AlCl4, CuCl2. The physical properties of ionic liquids depend on the kind of cation and anion. Quaternary ammonium salts, which have been known about for more than a century, exhibit interesting and

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Preparation of Samples for Analysis: The Key to Analytical Success

unique characteristics. In the 1940s, their powerful antibacterial properties were discovered; later, these compounds started to be used as phase transfer catalysts. At present, ionic liquids, also known as room-temperature ionic liquids, nonaqueous ionic liquids, molten salts, liquid organic salts, and fused salts, are considered to be the new generation of solvents. In chemical abstracts, they can be found under the headings “ionic liquid” or “liquids ionic.” Publications on ionic liquids are increasing in number. The first ammonium salt to be recognized as an ionic liquid was obtained in 1914. It was a nitrate with the structure [C2H5NH3] +NO3-. Many ionic liquids at present being examined were tested in the USA in the 1970s as electrolytes for batteries (the research was financed by the Air Force Office of Scientific Research). It was found that ionic liquids • Dissolve both organic compounds (from simple solvents to polymers) and inorganic ones (including some rocks and carbon) • Are thermally stable: their boiling point is high, often in excess of 350°C • Do not usually mix with water • Are nonvolatile (the vapor pressure at 25°C is very low) • Dissolve catalysts, especially transition metal complexes, without damaging the walls of a glass or steel reactor The temperature range within which ionic liquids occur in the liquid state is very characteristic; it is assumed that it is never greater than 300ºC. No other type of commonly used solvent occurs as a liquid over such a great range. Table 19.7 lists the physicochemical properties of frequently used solvents. With the use of ionic liquids, it is possible to investigate the kinetics of reactions over a much greater temperature range than before (it has been noted that some reactions occur faster at lower temperatures, a topic open to debate). These liquids are not normally miscible with water and are heavier than it, which is why there is no distinct phase border. Salts containing a tetrafluoroborate or hexafluorophosphate (V) anion are stable in air and in contact with water, but salts containing a tetrachloroaluminum ion are sensitive to water, reacting violently with it to produce toxic hydrogen chloride. The extraction of organic compounds from water using ionic liquids takes place in the same way as with traditional organic solvents.

TABLE 19.7 Physicochemical Properties of Popular Solvents Solvent Ammonium

TW - TT (°C)

TT (°C)

TW (°C)

- 78 5 0

75 100 124

44

- 63

- 34 80 100 61

Acetone

- 94

56

150

Ethyl acetate

- 84

77

161

Methanol

- 98

65

163

Hexane

- 95 6

69

164

- 61

211 153

205 215

~ -96

>200

>300

Benzene Water Chloroform

Nitrobenzene N,N-dimethylformamide Ionic liquid

Notes: TT, melting point; Tw, boiling point; and (TW - TT), temperature range in which solvent is a liquid.

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19.12 MICROWAVE-ENHANCED CHEMISTRY (MEC) The literature underscores the increasing importance of microwave radiation in the chemical laboratory. 2450 MHz radiation was first applied in microwave ovens, but some time later it was observed that this radiation can be used to heat different liquids and solids. It may be said that microwave ovens were the precursors of this new direction in analytics. In an analytical laboratory, at different stages of preparation of samples for analysis, microwave radiation28,218 supports the process of analyte extraction. Microwave-assisted extraction (MAE) was introduced to the scientific community in 1986.43 Initially used in the food and agricultural industries for conditioning food products, microwaves have been used for sample digestion since the mid-1980s. More recently, they have been used in the solvent extraction of organic analytes from a solid sample. Enhancement is based on the absorption of microwave energy by molecules of chemical compounds. The most frequently used solvents include dichloromethane and acetone–hexane mixtures. MAE can be carried out in two ways: 1. Pressurized MAE in closed vessels: This technique employs a microwave-transparent vessel for the extraction and a solvent with a high dielectric constant (electrical permittivity). Such solvents absorb microwave radiation and can thus be heated to a temperature exceeding solvent boiling points under standard conditions. Boiling does not occur, however, because the vessel is pressurized. This mode of operation is very similar to ASE—the elevated pressure and temperature facilitate extraction of the analyte from the sample. 2. Atmospheric MAE system: This second technique employs solvents with low dielectric constants. Such solvents are essentially microwave-transparent; they thus absorb very little energy, and extraction can therefore be performed in open vessels. The temperature of the sample increases during extraction because it usually contains water and other components with high dielectric constants: the process is thereby enhanced. Because extraction conditions are milder, this mode of operation can be used to extract thermolabile analytes. This technique is known as focused microwaves (FMW), and it also yields satisfactory results for polycyclic aromatic hydrocarbons, polychlorinated biphenyls (PCBs), organochlorine pesticides, and alkanes with the same advantages of security and ease of manipulation. Microwave heating is very efficient and can basically be explained by the interactions of an electric field with charged particles and polar molecules in a solution involving two mechanisms of energy absorption—ionic conductance and dipole rotation. However, problems arise in MAE when using apolar solvents, because microwave energy can only be effectively absorbed by molecules with dipole moments. For the extraction of organic contaminants this is a drawback, but the problem can be solved by increasing the polarity. The most important instruments for microwave extraction are a microwave radiation source, a waveguide, a resonant cavity, and an energy source. As waveguides are made of materials that strongly reflect electromagnetic waves (e.g., metal foils or metal sheets), microwave radiation passes from the magnetron to the receiver (resonator). The resonant cavity (resonator) is the part of the microwave apparatus from which microwave radiation is repeatedly reflected from its walls. The container with the sample to be extracted is placed in the resonator. MAE can use not only solvents that absorb microwave energy and have a high dielectric constant, but also those with a low dielectric constant that do not absorb microwave energy.220 In analyte extraction using solvents capable of absorbing a high level of microwave radiation (with a high dielectric constant), the extraction takes place at high temperatures. Because of the high pressure in the extraction vessel, the temperature of the solvent usually exceeds its boiling point, and may be as high as 300°C. In view of this, the vessel containing the sample and solvent must have special properties. Attention should be paid to the following points: (1) the chemical and thermal resistance of the material the vessel is made from, (2) its permeability to microwave radiation, and (3) its resistance to solvent action. The aforementioned requirements are fulfilled by containers

Preparation of Samples for Analysis: The Key to Analytical Success

455

made of polytetrafluoroethylene (PTFE), quartz, and certain composite materials. MAE has several advantages: • • • • •

A shorter heating and extraction time Compact devices Easy control of the sample heating process Reduced amount of solvent used for extraction Efficient use of energy (it is used solely to heat the sample and solvent)

It should be pointed out that several additional operations must usually be performed prior to the final determination: • Separation of the extract from the matrix (by filtration or decantation) • Concentration of the extract (removal of excess solvent) • Purification and drying of the extract Using the dynamic approach for extraction is generally advantageous, especially with respect to partitioning the solvent into the extraction media. This can be highly efficient when fresh solvent is continuously introduced into the extraction cell, that is, the rate constant for desorption need not be large compared with the rate constant for adsorption in order for the target solute to be removed efficiently. Another new approach combines MAE with the use of an aqueous surfactant solution as the extracting phase. This new technique is called microwave-assisted micellar extraction (MAME). This procedure is based on the well-known solubilization capacity of aqueous micellar solutions toward water-insoluble or sparingly soluble organic compounds. As a general rule, nonionic surfactants are usually the most effective, showing greater solubilization capacities that rapidly increase with the solubilization kinetics as the cloud-point temperature of the solution is raised. Table 19.8 presents information on the application of microwave radiation as an enhancing factor for other operations associated with sample preparation for analysis. The main characteristics of commercially available FMW technology are • Safety due to operation at atmospheric pressure. • The ability to handle large samples (mainly of organic materials) that may generate very large quantities of gas. • The use of different types of materials to construct reaction vessels, such as borosilicate glass, quartz, and PTFE. • The programmable addition of reagents at any time during the digestion, which makes allowance for sequential acid attack. • A low-power FMW field can be employed either to accelerate leaching of organometallic species without affecting carbon–metal bonds or to extract organic compounds. The focused nature of microwave energy is highly efficient and avoids the need for high power levels. • Multiple methods for different samples can be simultaneously applied, which allows for the independent operation of each reaction vessel.

19.13 APPLICATION OF ULTRASOUND (US) IN THE SAMPLE PREPARATION PROCESS Sound waves are mechanical vibrations in a solid, liquid, or gas and are intrinsically different from electromagnetic waves. While the latter (radio waves; infrared, visible, or ultraviolet light; X-rays; and gamma rays) can pass through a vacuum, sound waves must travel through matter, as they involve expansion and compression cycles traveling through a medium. Expansion pulls molecules apart, compression pushes them together.

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TABLE 19.8 Applications of Microwave Radiation in Sample Preparation for Analysis Sample Preparation Operation Desiccating Water (moisture) content determination Quick sample heating Microscopic sample preparation Sample incineration and melting Plasma incineration Activation of sample components in plasma Carrying out chemical reactions, including derivatization Steam distillation Pyrolysis Sample digestion Evaporization of aqueous solutions Microwave thermal inertization of wastes Heating of GC column MAE of samples

Reference The process may be carried out both under normal pressure and in a vacuum. Polar water particles are selectively heated204,220 and water evaporates221,222 Special instruments are used—microwave scale dryer Microwave radiation greatly enhances the fixing of biological material Microwave ovens use ceramic heaters, which are remotely heated by microwave radiation221 Plasma induced by microwave radiation (pressure of 10 mbar (1 kPa)) significantly decreases the incineration temperature The microwave-induced plasma (MIP) is used Microwave radiation can be used to accelerate the rate of chemical reactions62,223,224 99,225 226,227,228 Oxidation takes place in the medium of active reagents (nitric acid, hydrofluoric acid, hydrogen peroxide)229–233 221 Applied to asbestos-containing waste234 Negative temperature programming can be employed to enhance separation of compounds during the separation process235 The high efficiency of this type of extraction process enables it to be applied to the extraction of a wide spectrum of analytes from various matrices236,237–242

US is simply sound with a frequency higher than the range audible to humans (>16 kHz). The lowest US frequency is normally taken to be 20 kHz. The top end of the frequency range is limited only by the ability to generate the signals, so frequencies in the gigahertz (GHz) range have been used in some applications. The use of US in science has expanded in recent years, including such fields as medicine and industry where US has had the most impact; it continues to do so, with new uses appearing at regular intervals. Analytical chemistry has also availed itself of US energy—two of its aspects have been exploited [59]: a. It facilitates the development of different steps in the analytical process, related mainly to the preliminary steps involving solid samples. b. It improves detection (US has even been used as the actual means of detection). There are two common US devices for sample preparation applications: bath and probe units. Although US baths are more widely used, they have two main disadvantages that substantially reduce experimental repeatability and reproducibility243: a. A lack of uniformity in the distribution of US energy (only a small fraction of the total liquid volume in the immediate vicinity of the US source experiences cavitations) b. A decline in power with time US probes are superior to US baths, however, in that they focus their energy on a localized sample zone, thereby providing more efficient cavitations in the liquid. It has been demonstrated

Preparation of Samples for Analysis: The Key to Analytical Success

457

that, because of the formation of standing waves, the local intensity in a flask fixed in a US cleaner is highly susceptible to changes in experimental conditions, so precision is considerably affected as a result. Most US-assisted sample preparation applications are developed in discrete systems; nevertheless, continuous approaches mean that a given step can be automated, as it can be interfaced with others that are also automated. The performance of baths and probes in US-assisted digestion under soft or strong conditions depends on a number of factors that are rarely optimized in the development of US-assisted digestion methods. The variables affecting US-assisted digestion common to baths and probes are244 • The shape of the vessel containing the target chemical system, a factor usually ignored. Flat-bottomed vessels (e.g., conical flasks) are to be preferred because the energy transfer is more efficient. • The stirring of the target suspension; this can be advantageous because it ensures effective contact between the solid and the liquid during sonication. • The temperature of the medium can have a strong influence on the rate of digestion. In the case of thermolabile analytes, operation over very short periods of time or circulation of thermostatted cold water in the tank may be alternative means of controlling the temperature. • The influence of pressure on US-assisted digestion has hardly been studied at all. There are only a few cases of chemical reaction acceleration where high pressure has been applied in closed ultrasonic reactors. These devices can also be used as ultrasonic digestors. • Solvent properties affect US-assisted digestion, as they impose a cavitation threshold above which sonochemical effects are “perceived,” as it were, by the medium. Therefore, any phenomenon altering the same solvent property can modify such a threshold. • The radiation amplitude is directly related to the amount of energy applied to the system. Exhaustive treatments require high irradiation amplitudes, for which probes are more suitable than baths. • Particle size is a key variable, so digestion mechanisms are influenced by particle diameter. In fact, depending on particle size, simultaneous microstreaming and microjetting or some other effect can determine the efficiency of US-assisted digestion to a variable extent. There are other specific physical variables that influence digestion assisted by an ultrasonic probe, namely,244 • The depth of immersion into the sample vessel or bath containing the transmitting liquid has a decisive influence on the effect of ultrasonic probes. This is because virtually no sonication exists alongside the tip or above it. Therefore, if the probe is immersed only slightly, it will cause foaming at the liquid surface, resulting in a loss of US energy. On the other hand, if the probe is immersed too deeply, the energy supplied will be inadequately transmitted through the liquid and digestion efficiency will suffer as a result. • The probe-tip/sample-cell distance should be considered when the probe is inserted into the sample vessel. The shorter the distance, the less the attenuation, and the higher the energy applied to the sample as a result. • When ultrasonic energy is applied in a pulsed mode, pulse duration can be an important variable. US can be used as an enhancing agent during different steps of sample preparation for analysis: • Analyte extraction119,156,175,245,246: US-assisted extraction is an effective way of removing a number of analytes from different types of samples, as it combines several effects, namely,

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a. Extremely high effective temperatures, which result in increased solubility and diffusivity. b. High pressures, which favor penetration and transport at the interface between an aqueous or organic solution subject to US energy, and an organic or aqueous phase, or a solid matrix (which is more common). c. The oxidative energy of radicals created during sonolysis of the solvent (hydroxyl and hydrogen peroxide for water). • Digestion235 • Dissolution247 • Homogenization and emulsification84,158 • Filtration248 • Analytical reactions (e.g., derivatization)137 • Reagent generation36 • Slurry formation59 • Cleaning46 • Degassing.249 It is worth emphasizing two main constraints in the use of US in the field: a. US energy can lead to undesirable deterioration of sample components, so special care must be taken to ensure that only the desired effect is produced in a US-treated system. b. The use of the appropriate US device is key to obtaining a given effect that cannot be produced by devices designed for other, different tasks. For example, US baths may be designed for cleaning purposes, for which power stability or uniformity in the distribution of US energy is not mandatory. Even considering that microwave technology has improved some traditional operations in chemistry, there is still a long road ahead, since only some 10% of laboratories throughout the world are equipped with laboratory-designed microwave ovens.232

19.14 GREEN CHEMISTRY: INTRODUCTION OF THE CONCEPT OF SUSTAINABLE DEVELOPMENT TO CHEMICAL LABORATORIES 19.14.1

HISTORY

The term “green chemistry” was fi rst used in 1991 by P.T. Anastas in a special program launched by the US Environmental Protection Agency (EPA) to implement sustainable development in chemistry and chemical technology by industry, academia, and government. In 1995, the annual US Presidential Green Chemistry Challenge was announced. Similar awards were soon established in European countries. In 1996, the Working Party on Green Chemistry was created, acting within the framework of the International Union of Applied and Pure Chemistry. One year later, the Green Chemistry Institute (GCI) was formed with chapters in 20 countries. Its aim was to facilitate contact between governmental agencies/industrial corporations and universities/ research institutes in the design and implementation of new technologies. The fi rst conference highlighting green chemistry was held in Washington in 1997. Since that time, other similar scientific conferences have been held on a regular basis. The first books and journals on the subject of green chemistry were introduced in the 1990s, including the Journal of Clean Processes and Products (Springer-Verlag) and Green Chemistry, sponsored by the Royal Society of Chemistry. Other journals, such as Environmental Science and Technology and the Journal of Chemical Education, have sections devoted to green chemistry. The latest information can also be found on the Internet.

Preparation of Samples for Analysis: The Key to Analytical Success

459

The concept of green chemistry arose in the United States as a joint research program resulting from the interdisciplinary cooperation of university teams, independent research groups, industry, scientific societies, and governmental agencies, each with their own programs aiming at reducing pollution. Green chemistry incorporates a new approach to the synthesis, processing, and application of chemical substances in such a manner as to reduce threats to health and the environment. This new approach is also known as • • • •

Environmentally benign chemistry Clean chemistry Atom economy Benign-by-design chemistry.

Green chemistry is commonly presented as a set of Twelve Principles proposed by Anastas and Warner—they are a set of instructions for professional chemists to be adhered to when synthesizing new chemical compounds and implementing new technological processes.250 Green chemistry is not a new branch of science. It is a new philosophical approach which, through its application and extension of principles, can contribute to sustainable development. Numerous interesting examples of the use of green chemistry rules lie to hand. In addition, new analytical methodologies that can be implemented in accordance with green chemistry standards are being developed; they will be useful in carrying out chemical processes and in the evaluation of their effects on the environment.

19.14.2

GREEN ANALYTICAL CHEMISTRY

The irony is that the analytical methods used by analytical chemists in laboratories to assess the state of environmental pollution, through uncontrolled disposal of reagents and solvents or chemical waste, may in fact be a source emitting large amounts of pollutants that adversely affect the environment. This is because considerable quantities of chemical compounds need to be used in the successive steps of analytical procedures. Sampling, and especially the preparation of samples for their final determination, frequently involves the formation of large amounts of pollutants (vapors, reagent and solvent wastes, and solid waste). The rules of green chemistry therefore need to be introduced into chemical laboratories right across the board. If we look at the Twelve Principles of Green Chemistry, it is easy to indicate the issues that should determine the “green” character of analytical chemistry. The following should be treated as priorities251,252: • Eliminating or minimizing the use of chemical reagents, particularly organic solvents, from analytical methods. • Eliminating highly toxic and ecotoxic chemicals from analytical procedures. • Reducing labor- and energy-intensive steps in particular analytical methods (per single analyte). • Reducing the impact of chemicals on human health. The development of analytics and environmental monitoring leads to better knowledge of the state of the environment and the processes that take place in it. As a result of the introduction of new methodologies and new measuring techniques for identifying and determining trace and microtrace components in samples with complex compositions into analytical practice, the following important circumstances have been established: • The acidification of certain components of the environment • The existence of stratospheric ozone depletion

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Analytical Measurements in Aquatic Environments

• The existence of long-term trends in the changes of trace components in atmospheric air • The presence of elevated concentrations of POPs, for example, dioxins [polychlorinated dibenzodioxin (PCDD) and polychlorinated dibenzofuran (PCDF)] and PCBs • The bioaccumulation of pollutants in the tissues of organisms at different levels of the trophic pyramid This branch of analytical chemistry presents many challenges. The most important are • • • •

The low and very low concentration levels of analytes The existence of temporal and spatial fluctuations of analytes in the investigated media A broad range of concentrations of analytes belonging to the same group of compounds The possibility of the presence of interfering compounds, frequently with similar chemical structures and properties

The techniques of sample preparation, extraction (isolation), and/or preconcentration of analytes are usually applied in the analysis of trace components of gaseous, liquid, and solid samples. During this operation, transport of analytes from primary matrices (donors) to the secondary matrix (the acceptor) takes place. It should be remembered, however, that the extraction and preconcentration steps could be a source of environmental pollution. The techniques of sample preparation introduced in this chapter have the following advantages253: • They are solvent-free or virtually so—solvent usage per one analysis is reduced to a minimum. • The transport of analytes to the matrix is characterized by simplicity of composition compared with primary matrices, and is more suitable and compatible with the analytical technique used in the final determination step. • The removal, or at least reduction, of interfering substances as a result of the selective transfer of sample components to the acceptor matrices. • Increased concentration of analytes in the acceptor matrix to levels over the limit of quantitation for the chosen analytical technique. There is an urgent need to evaluate the applied analytical methods, with respect not only to the reagent, instrumental costs, and analytical parameters, but also to their negative influences on the environment. A good tool for such evaluation is life cycle assessment (LCA). The introduction of LCA as a tool for examining the environmental burden of various analytical techniques may revolutionize the field of analytics. In rating analytical techniques according to their influence on the environment, one should apply a holistic approach that will include • • • • •

The output of raw materials The production of reagents and energy The transport of raw materials and final products The influence of a given reagent on the environment in the process of its usage The storage and recycling of chemical waste and out-of-date reagents

Green analytical chemistry is an essential component of green chemistry. The ongoing development of new solvent-free techniques is a good example of activities in this field. The following direct analytical techniques (in which a preparation step is not necessary) may be treated as typical examples of environmentally friendly procedures: • X-ray fluorescence • Surface acoustic waves (SAW) for the determination of VOCs • Immunoassay.

461

Preparation of Samples for Analysis: The Key to Analytical Success

In addition, other techniques, in which quantities of reagents and solvents per one analytical cycle are limited, are part of environmentally benign procedures. These include • • • • • • • • •

SPE ASE SPME Micro liquid-liquid extraction (MLLE) and other microextraction techniques Ultrasonic extraction SFE Extraction in an automated Soxhlet apparatus Vacuum distillation of VOCs Mass spectrometry with membrane interface (MIMS)

The extraction of pesticides from soil samples using accelerated solvent extraction is a good example of an analytical procedure fulfilling the rules of green chemistry. This procedure has many advantages over the classical techniques used for extracting analytes from complex matrices. The main advantages regarding green chemistry are that • Solvent use is reduced (by up to 95%). • Analysis time is shortened (from 16 h to 10 min). • Energy is saved (the extraction cell of an ASE instrument heats up to 100°C in 10 min in comparison to the 16 h required to heat a plate in a Soxhlet apparatus), thereby reducing exposure to solvents because of the shorter extraction time and the smaller amounts of solvents. • Similar analytical characteristics for smaller samples (ASE). This procedure can be treated as an alternative to the commonly used Soxhlet extraction. Table 19.9 compares various solvent extraction techniques with regard to the duration and the amount of the solvent used (per 1 sample), and Figure 19.7 presents basic information on the main groups of solvent-free techniques in the context of sample preparation for analysis. Thermal desorption enables the exchange of solvent into a more environmentally friendly stream of gas at the stage where analytes are being released into a suitable trap (sorption tube, denuder, and passive dosimeter). Figure 19.8 illustrates the basic mechanisms of the thermal desorber. The ability to rapidly assess or monitor the disposition of environmental contaminants at purported or existing hazardous waste sites is an essential component of green chemistry. Soil samples, which represent approximately half the total number, are extracted with solvents, and then further separated using additional solvent to produce chemical-specific fractions. Each fraction is then analyzed using an appropriate method. The new technology proposed at the Tufts

TABLE 19.9 Comparison of Solvent Extraction Techniques Extraction Technique Soxhlet extraction Automated Soxhlet extraction US-enhanced solvent extraction Microwave-enhanced solvent extraction Accelerated solvent extraction SFE

Amount of Solvent Used (mL) 200–500 50–100 100–300 25–50 15–40 8–50

Mean Duration of the Extraction Process 4–48 h 1–4 h 30 min–1 h 30 min–1 h 12–18 min 30 min–2 h

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Analytical Measurements in Aquatic Environments

Solventless techniques of samples for GC analyses

Extraction of analytes from sample with a stream of gas

Membrane extraction

Direct determination of analytes in a stream of gas (Head Space Analysis – HSA)

Trapping analytes in a chromatographic column (Whole Column Cryotrapping – WCCT)

Freezing analytes and their thermal releasing priori to the determination stage (Cryotrapping – CT )

Direct determination of analytes in a stream of gas or liquid flushing the external side of membrane

Dosage of analytes into a mass spectrometer (Membrane inlet Mass Spectrometry –MMS)

Collection of analytes from a stream of gas on a sorbent bed and their release by thermal decomposition priori to the final determination stage, (Membrane Extraction with Sorbent Interface – MESI), (Hollow Fiber Sampling Analysis – HFSA), (On-line Membrane Extraction Microtrap – OLME), (Membrane Purge and Trap – MPT), (Pulse Introduction Membrane Extraction – PIME), (Semi Permeable Membrane Devices – SPMD)

Utilization of an extraction membrane as analyte collecting medium in combination with thermal desorption (Thermal Membrane Desorption Application – TMDA)

Utilization of passive dosimeters of permeation type of analyte collection stage and thermal desorption of their release

Solid phase extraction (SPE)

Supercritical fluid extraction (SFE)

Utilization of traps with a suitable solid sorbent (Purge and Trap – PT), (Closed Loop Stripping analysis – CLSA), – or a stationary phase on a support - packed PDMS trap – sorption tubes, denuders, passive dosimeters - combined with thermal desorption –TD at the release stage.

Utilization of a sorbent bed inside the syringe needle for a sample collection–(Inside Needle Capillary Absorbtion Trap – INCAT)

(Solid Phase Microextraction – SPME), sampling the analytes directly from the medium of interest (gas, liquid)

Sampling of the head space (Head Space- Solid Phase MicroextractionHS – SPME)

Utilization of a part of capillary column as an extraction element and thermal desorption for the release of analytes (Coated Capillary Microextraction – CCME), (Thick Film Open Tabular Trap – TFOT), (Thick Film Capillary Trap – TFCT)

FIGURE 19.7 Classification of solvent-free techniques in the context of sample preparation for analysis.

University (MA, USA) aims at reducing or eliminating solvent usage during sample collection and analysis by collecting and detecting organic pollutants in situ without bringing the actual soil sample to the surface. A thermal extraction cone penetrometry probe coupled to an ultrafast gas chromatography-mass spectrometer (TECP-TDGC-MS) has been developed to collect and analyze subsurface organic contaminants in situ. The TECP is capable of heating the soil to 300°C, which is sufficient to collect volatile and semivolatile organics bound to the soil, in the presence of a soil– water content as high as 30%. Rather than using solvents to extract organics from soil, the TECP

1

1

2

Carrier gas

Capillary GC column

FIGURE 19.8

Diagram of a thermal desorber.

2

Carrier gas

Capillary GC column

Preparation of Samples for Analysis: The Key to Analytical Success

463

uses heat, then traps the hot vapor in a Peltier-cooled thermal desorption GC sample inlet for online analysis. In addition, this technology reduces solvent usage during the decontamination of sample collection probes and the apparatus used to homogenize samples. No other technology exists that is capable of thermally extracting organics as diverse as PCBs, explosives, or polyaromatic hydrocarbons (PAHs) under these conditions. When combined with the Ion Fingerprint Detection TM software, ultrafast TDGC-MS is capable of analyzing complex environmental samples in less than 5 min. The next important challenge of green analytical chemistry is in-process monitoring. Developing and using in-line or on-line analyzers allow analytes to be determined in real time, in turn enabling disturbances to be detected already in the initial steps of a process. Such a means of analysis provides rapid information and the chance of an appropriate response—stopping the process or changing its operational parameters—and improves overall efficiency. The application of green chemistry rules in designing greener analytical methods is key to diminishing the negative effects of analytical chemistry on the environment. The same ingenuity and innovatory skills, applied earlier to obtain excellent sensitivity, precision, and accuracy, are now being used to reduce or eliminate the application of hazardous substances in environmental analytics.

19.15

SUMMARY AND CONCLUSION

The chapter reviews the literature on the individual stages of environmental sample preparation up to the stage of final determinations with regard to analytes occurring in low concentrations. Special attention is paid to • • • •

Challenges related to speciation analytics State-of-the-art techniques of extraction and analyte enrichment The use of US and microwave radiation at each stage of analytical procedures The implementation of principles associated with the concept of sustainable development in the procedures used in analytical laboratories

Analytical research is usually labor- and time-consuming as well as expensive, and thus its end result should provide authoritative and reliable information. Because of this, the following conditions must be fulfilled: • A sample must be representative with regard to the examined object material. • A sample must be properly prepared for analysis. • A sample analysis should be carried out with suitable control and measurement instruments that cannot be treated as a blank.

REFERENCES 1. Konieczka, P. and J. Namies´nik. 2007. Ocena i kontrola jakos´ci wyników pomiarów analitycznych. Warszawa: WNT. 2. Thomas, O. and M.-F. Pouet. 2005. Wastewater quality monitoring: On-line/on-site measurement. Handbook Environ. Chem. 5: 245–272. 3. Saito, Y. 2003. Miniaturization of separation systems and its applications. Chromatography 24: 7–17. 4. Wang, J. and E.H. Hansen. 2003. On-line sample-pre-treatment schemes for trace-level determinations of metals by coupling floe injection or sequential injection with ICP-MS. Trends Anal. Chem. 22: 836–845. 5. Theodoridis, G. and I.M. Papadoyannis. 2001. Modern sample preparation methods in chemical analysis. Microchim. Acta 136: 199–200. 6. de Oliviera, E. 2003. Sample preparation for atomic spectroscopy: Evolution and future trends. J. Braz. Chem. Soc. 14: 174–182.

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236. Hildebrandt, A., S. Lacorte, and D. Barcelo. 2006. Sampling of water, soil and sediment to trace organic pollutants at a river-basin scale. Anal. Bioanal. Chem. 386: 1075–1088. 237. Sun, Y., M. Takaoka, N. Takeda, T. Matsumoto, and K. Oshita. 2006. Application of microwave-assisted extraction to the analysis of PCBs and CBzs in fly ash from municipal solid waste incinerators. J. Hazard. Mater. A 137: 106–112. 238. Pino, V., J.H. Ayala, A.M. Afonso, and V. Gonzalez. 2003. Micellar microwave-assisted extraction combined with solid-phase microextraction for the determination of polycyclic aromatic hydrocarbons in a certified marine sediment. Anal. Chim. Acta 477: 1–91. 239. Serrano, A. and M. Gallego. 2006. Continuous microwave-assisted extraction coupled on-line with liquid–liquid extraction: Determination of aliphatic hydrocarbons in soil and sediments. J. Chromatogr. A 1104: 323–330. 240. Morales-Munoz, S., J.L. Luque-Garcia, and M.D. Luque de Castro. 2004. Screening method for linear alkylbenzene sulfonates in sediments based on water Soxhlet extraction assisted by focused microwaves with on-line preconcentration/derivatization/detection. J. Chromatogr. A 1026: 41–46. 241. During, R.A. and S. Gath. 2000. Microwave assisted methodology for the determination of organic pollutants in organic municipal wastes and soils: Extraction of polychlorinated biphenyls using heat transformer disks. Fresenius J. Anal. Chem. 368: 684–688. 242. Capadoglio, C. 1997. Sampling techniques for sea water and sediments. In: A. Gianguzza, E. Pelizzetti, and S. Sammartano (eds), Marine Chemistry,. pp. 115–130. Dordrecht: Academic Kluwer Publisher. 243. Priego-Capote, F. and M.D. Luque de Castro. 2007. Ultrasound-assisted digestion: A useful alternative in sample preparation. J. Biochem. Biophys. Meth. 70: 299–310. 244. Capelo, J.L., P. Ximenez-Embun, Y. Madrid-Albarran, and C. Camara. 2004. Enzymatic probe sonication: Enhancement of protease-catalyzed hydrolysis of selenium bound to proteins in yeast. Anal. Chem. 76: 233–237. 245. Xiao, H.B., M. Krucker, K. Albert, and X.M. Liang. 2004. Determination and identification of isoflavonoids in Radix astragali by matrix solid-phase dispersion extraction and high-performance liquid chromatography with photodiode array and mass spectrometric detection. J. Chromatogr. A 1032: 117–124. 246. Yang, Z., S. Matsumoto, and R. Maeda. 2002. Comparison of dynamic transient- and steady state measuring methods in a batch type BOD sensing system. Sens. Actuat. A 95: 274–280. 247. Wang, R.Y., J.A. Jarratt, P.J. Keay, J.J. Hawkes, and W.T. Coakley. 2000. Development of an automated on-line analysis system using flow injection, ultrasound filtration and CCD detection. Talanta 52:129–139. 248. Yang, L. and J.W. Lam. 2001. Microwave-assisted extraction of butyltin compounds from PACS-2. Sediment for quantitation by high-performance liquid chromatography inductively coupled plasma mass spectrometry. J. Anal. At. Spectrom. 16: 724–731. 249. Namies´nik, J. and W. Wardencki. 2000. Solventless sample preparation techniques in environmental analysis. J. High Resol. Chromatogr. 23: 297–303. 250. Jermak, S., B. Pranaityte, and A. Padarauskas. 2007. Ligand displacement, headspace single-drop microextraction, and capillary electrophoresis for the determination of weak acid dissociable cyanide. J. Chromatogr. A 1148: 123–127. 251. Afzali, D., A. Mostafavi, M.A. Taher, and A. Moradian. 2007. Flame atomic absorption spectrometry determination of trace amounts of copper after separation and preconcentration onto TDMBAC-treated analcime pyrocatechol-immobilized. Talanta 71: 971–975. 252. Curyło, J., W. Wardencki, and J. Namies´nik. 2007. Green aspects of sample preparation—a need for solvent reduction. Polish J. Environ. Stud. 16: 5–16. 253. Harmel, R.D., R.J. Cooper, R.M. Slade, R.L. Haney, and J.G. Arnold. 2006. Cumulative uncertainty in measured streamflow and water quality data for small watersheds. Amer. Soc. Agri. Biol. Eng. 49: 689–701.

Index A AAS. See Atomic absorption spectroscopy Absorbents, 45 Absorption, 45, 74 Absorption spectrophotometry, 264 Absorptivity, 264 Accelerated solvent extraction (ASE), 356–357 Acidic herbicides, 28 AdCSV. See Adsorptive cathodic stripping voltammetry Addition of poisons (biocides), 21 Adsorption, 45, 74 Adsorptive cathodic stripping voltammetry (AdCSV), 126 Advanced oxidation processes (AOPs) for water sample preparation, 96 ozone oxidation, 98–99 UV photo-oxidation, 97–98 AEs. See Alkyl ethoxylates AES. See Alkyl ether sulfates AFS. See Atomic fluorescence spectrometry Agriculture, 305 Air–acetylene flame, 267 Algal toxins, passive sampling, 55–56 Aliphatic hydrocarbons, 30 Alkyl ether sulfates (AES), 145 Alkyl ethoxylates (AEs), 145, 146 Alkyl sulfonates (AS), 145 Alkyl-trialkoxysilanes, 313 Alkylphenol ethoxylate, 145, 329, 332 Aluminum, 13, 285 Ammonium determination, indophenol blue method for, 404–405 Amphenicols detection, 162–163 Analyte derivatization, 325–326 Analyte extraction, modern techniques of liquid membrane based techniques microporous membrane liquid–liquid extraction, 84–87 supported liquid membrane (SLM) extraction, 79–84 two-phase HF-LPME, 87–88 miniaturized nonmembrane-based extraction techniques miniaturized liquid-phase extraction techniques, 70–72 miniaturized SPE techniques, 72–73 solid-phase microextraction, 73–75 stir bar sorptive extraction, 75 nonporous polymeric membranes based techniques, 75–76 membrane-assisted solvent extraction, 78–79 membrane extraction with sorbent interface, 76–77

membrane inlet (introduction) mass spectrometry (MIMS), 76 Analytical data, types of, 434–435 Analytical procedure for organic compounds determination, 27–28 stages of, 440–442 Analytical protocols, 7–8 Analytical results, QA/QC monitoring of, 394–395 external QC, 395–396 internal QC, 395 traceability, 394 validation of analytical procedures, 393–394 Analytical techniques, of inorganic constituents, 261 atomic spectrometry, 265–272 automatic analyzers and monitoring, 281–282 chemical vapor generation-atomic spectrometry (CVG-AS), 273–275 electrochemical techniques, 275–278 gravimetric measurements, 262 mass spectrometric techniques, 272–273 separation techniques, 278–281 spectrophotometric technique instrumentation, 264–265 on molecular absorption radiation, 263 trimetric measurement, 262 Androgens, immunochemical determination of, 168–169 Animals, differential tissue analysis, 110–111 Anodic stripping voltammetry (ASV), 126, 275–276 Antibiotics, detection of, 158–160, 165–166 amphenicols, 162–163 b-lactams, 164 fluoroquinolones, 161–162 macrolides, 165 sulfonamides, 160–161 tetracyclines, 163–164 Aquatic ecosystem inorganic constituents in, 260 speciation analytics in. See Speciation analytics AOC. See Assimilable organic carbon AOPs. See Advanced oxidation processes API. See Atmospheric pressure ionization APPI. See Atmospheric pressure photo-ionization ARGE-Elbe project, 209 Arsenic speciation, 122 electrochemical speciation, 126–127 hyphenated methods chemiluminescence and colorimetric reactions, 128 chromatography, 127–128 exchange columns, 127 in situ speciation, in aquatic system, 123–125 sample preservation and storage, 126 sampling, 125

475

476 AS. See Alkyl sulfonates As speciation. See Arsenic speciation ASE. See Accelerated solvent extraction Assimilable organic carbon (AOC), 232 ASV. See Anodic stripping voltammetry At-line solid phase extraction, 321 Atmospheric microwave-assisted extractions, 454 Atmospheric pressure ionization (API), 311, 317 Atmospheric pressure photo-ionization (APPI), 317 Atomic absorption spectroscopy (AAS), 224, 243, 405 Atomic emission spectrometry (AES), 270 Atomic fluorescence spectrometry (AFS), 228, 230, 271–272 atomizers, 272 radiation, source of, 271 Atomic spectrometry, 265 atomic emission spectrometry, 270 atomic fluorescence spectrometry, 271–272 electrothermal atomic absorption spectrometry, 268–269 flame atomic absorption spectrometry, 266–268 high-resolution continuous source atomic absorption spectrometry, 269–270 inductively coupled plasma-optical emission spectrometry (ICP-OES), 270–271 Atomizer, 268, 272, 275 Automated flowing MMLLE off-line systems, 84, 86–87 nonautomated, nonflowing design, 86–87 on-line systems, 84–85 syringe device extraction, 85–86 Automated water analyzer computer supported system (AWACSS), 160 Automatic analyzers and monitoring, 281–282 Automatic sampling system, 42 Automatic water sampling systems, 14 basic components, 15 Average linkage method, 372–373 AWACSS. See Automated water analyzer computer supported system AZUR Environmental, 196

B Background correction, 267 Badge-type samplers, 46 Batch analyzer. See Discrete analyzer Beer–Lambert law, 408 Benzalkonium surfactants, 32 Benzio(a)pyrene, 143 b-lactams (BL), detection of, 164 BEWS. See Biological Early Warning Systems Biacore Q, 163 Biacore SPR sensor, 164 Bias, 47 Bioassays, 56 Biochemical oxygen demand (BOD), 14, 224, 232 determination of, 225 limitations of, 225 Biocides, 21 Bioconcentratable hydrophobic estrogen receptor agonists, 56 Biofouling, 48–50 Bioindicator organisms, 198

Index Bioindicator techniques, 104, 196 standard and guidelines for performing toxicity tests using, 194–195 Biological Early Warning Systems (BEWS), 192–193 Biological oxygen demand (BOD), 192, 374, 377 Bioluminescent bacteria, 196 Biomonitoring, 42, 104 passive sampling, 57 Biosensors, 144 Biota, 57 mineralization of, 251 Biota analysis as information source, in state of aquatic environments, 103 assessment strategies, 109–110 animals, differential tissue analysis, 110–111 plants, contaminants accumulation and partitioning, 110 species choice pelagic species, 108–109 primary producers, 105–106 sediment dwellers, 107–108 suspension feeders, 106–107 supplementary methodologies metallothioneins, 113–114 oxidative stress, 112–113 Biotests, 189, 328 environmental monitoring, bioassay application in, 210 hot spots, identification of, 211–212 monitoring parameters, revision of, 214–216 polluted areas managed by specific areas, ranking of problems in, 212–214 toxic compounds, identification of, 210–211 environmental pollution extent assessment, chemical monitoring in, 190–192 environmental samples, ecotoxicological classification of, 201, 207–210 legal regulations applicable to toxicity measurement, 201, 205–207 toxicity tests, importance of, 192–195 Toxkit tests, 195–199 water pollution assessment, integrated system of, 200 Biotoxins adsorption, 55 Bisphenol A (BPA), 150–151 BL. See b-Lactams BOD. See Biochemical oxygen demand; Biological oxygen demand Borosilicate glass, 13 Botanical pesticides, 28 Bouguer–Lambert–Beer law, 263 BPA. See Bisphenol A Brass, 13 British Standards Institute Publicly Available Specification (BSI PAS-61), 57 BSI PAS-61. See British Standards Institute Publicly Available Specification

C C18 stationary phases, 313 CA. See Cluster analysis CAP detection. See Chloramphenicols detection Capillary electrophoresis (CE), 127, 280–281, 309, 313–315 Capillary gel electrophoresis (CGE), 281

477

Index Capillary isoelectric focusing (CIEF), 281 Capillary isotachophoresis (CITP), 281 Capillary microextraction (CME), 127 Capillary zone electrophoresis (CZE), 281 Carbamates, 28 Carbon steel, 13 Carcinus maenas, 111, 114 Cathodic stripping voltammetry (CSV), 126, 231 Cationic surfactants, 145 CCDs. See Charge-coupled devices; Chlorinated cyclodienes CE. See Capillary electrophoresis Ceramic dosimeters, 15 Ceramics, 13 Ceriodaphnia dubia, 198 Certified reference materials (CRMs), 391, 395, 396 Cesium determination, 246–248 activity calculation, 247 separation by adsorption on AMP, 246–247 CFA. See Continuous flow analysis CFC. See Chlorofluorocarbons CFME. See Continuous-flow microextraction CGE. See Capillary gel electrophoresis Charge-coupled devices (CCDs), 266–270 Charm II RIA, 160, 164 Chelex-based sorption phase, 55 Chemcatcher, 46, 48, 54 Chemical ionization (CI), 317 Chemical measurements, quality in, 390–391 Chemical modification. See Matrix modification Chemical oxygen demand (COD), 192, 225, 231–232, 377 limitations of, 225 Chemical speciation, 224 Chemical vapor generation (CVG), 266, 274 Chemical vapor generation-atomic spectrometry (CVG-AS), 273–275 Chemiluminescence and colorimetric reactions, 128 Chemiluminescence enzyme immunoassay (CLEIA), 167 Chemometrics, 369 definition, 370 methods, 370 cluster analysis (CA), 370–376 principal component analysis (PCA), 380–383 receptor modeling, 383–385 self-organizing maps (SOM), 376–379 Cherenkov counting technique, 242, 249 Chiral speciation, 438 Chloramphenicols (CAPs) detection, 158, 162–163, 164 Chloride mercury thiocyanate-iron method for, 405 Chlorinated cyclodienes (CCDs), 152 Chlorinated hydrocarbons, 28 Chlorofluorocarbons (CFC), 13 Chlorophenoxy acid herbicides, 156 Chlorsulfuron, detection of, 157–158 Chromatography, 127–128, 318–325, 439 Chromium speciation, 26, 122 electrochemical speciation, 126–127 hyphenated methods chemiluminescence and colorimetric reactions, 128 chromatography, 127–128 exchange columns, 127 in situ speciation, in aquatic system, 123–125

sample preservation and storage, 126 sampling, 125 CI. See Chemical ionization CIEF. See Capillary isoelectric focusing CITP. See Capillary isotachophoresis Clarias gariepinus, 113 Clark electrode, 276 Class weight score, calculation of, 208 Classical analytical methods, 191 CLEIA. See Chemiluminescence enzyme immunoassay CLTRAP. See Convention on Long-range Transboundary Air Pollution Cluster analysis (CA) case study (Struma River), 373–376 theoretical principles, 370–373 Clustering algorithms, 371 CME. See Capillary microextraction Coacervates, 32 COC. See Cold-on-column COD. See Chemical oxygen demand Cold vapor atomic fluorescence spectrometry, 130, 408 Cold-on-column (COC) injection, 309 Cold-vapor atomic absorption spectrometry, 231 Colonization of organisms, 48 Complete linkage method, 372 Composite water sample, 3–4 Conductivity, of precipitation samples, 403–404 Containers, 20 Continuous analyzer, 281 Continuous flow analysis (CFA), 281 Continuous-flow microextraction (CFME), 71–72 Control charts, 391, 395 Convention on Long-range Transboundary Air Pollution (CLTRAP), 400 Conversion reactions, 27 Copper, 13 Corbicula fluminea, 111 Corticosteroids, immunochemical determination of, 169 Cosolvent method, 47 Council Directive 76/464/EEC, 141, 191–192 Council Regulation 793/93, 193 Cr speciation. See Chromium speciation Crassostrea gigas, 114 CRMs. See Certified reference materials 137Cs determination. See Cesium determination CSV. See Cathodic stripping voltammetry Cusum charts, 395 CV/HG methods. See CVG methods CVG. See Chemical vapor generation CVG-AS. See Chemical vapor generation-atomic spectrometry CZE. See Capillary zone electrophoresis

D Daphni pulex, 198 Daphnia magna, 198, 207 Data quality control, 409–410 DDT. See Dichloro-diphenyl-trichloroethane Deca-BDE, 148 Deep-water samplers, 14 Derivatization. See Analyte derivatization DET. See Diffusive Equilibrium in Thin Films Detection limit, for different analytical methods, 406

478 Detection techniques, for organic and organometallic pollutants, 315 Fourier-transform ion cyclotron resonance instruments, 317 inductively coupled plasma-mass spectrometry, 318 ion trap mass spectrometers, 316 ionization techniques, 317 quadrupole mass spectrometers, 316 time-of-flight (TOF) instruments, 317 triple quadrupole mass spectrometers, 316–317 DGT sampler. See Diffusive gradients in thin films DIC. See Dissolved inorganic carbon Dichloro-diphenyl-trichloroethane (DDT), 14 Diclofenac, detection of, 165 Diffusion barrier, 45 Diffusion flames, 272 Diffusion-based samplers, 46 Diffusive Equilibrium in Thin Films (DET) sampler, 123 Diffusive gradients in thin films (DGT) sampler, 46, 55, 123, 125 DIHN. See Direct injection high efficiency nebulizers Dimethyl mercury (DMHg), 26, 129 analytical methods for determination, 130 DIN 38412, 197 Dioxin, 30, 142 Direct immersion SPME (DI-SPME), 358 Direct injection high efficiency nebulizers (DIHN), 271 Direct injection nebulizers, 271 Direct toxicity assessment (DTA), 200 Discharge-proportional sampling, 4 Discontinuous sampling techniques, 4 Discrete analyzer, 281 Discrete water sample, 3 Dispersive liquid–liquid microextraction (DLLME), 72 Dispersive solvent, 72 DI-SPME. See Direct immersion SPME Dissolved gases determination methods, 290 Dissolved inorganic carbon (DIC), 232 Dissolved organic carbon (DOC), 30, 47, 225, 233 Dissolved organic matter (DOM), 96 Dissolved organic sulfur, 233 Distribution speciation, 438 Divinylbenzene polymeric resins, 55 Divisive algorithms, 371 DLLME. See Dispersive liquid–liquid microextraction DLPME. See Dynamic liquid-phase microextraction DME. See Dropping mercury electrode DMHg. See Dimethyl mercury DOC. See Dissolved organic carbon DOM. See Dissolved organic matter Double check-valve bailer with a bottom-emptying device, 14 Double-focusing magnetic sector mass analyzer, 273 Dredges, as sediment samplers, 12, 15 Dropping mercury electrode (DME), 275 DTA. See Direct toxicity assessment Dynamic liquid-phase microextraction (DLPME), 71

E ECD. See Electron capture detection EcHG. See Electrochemical hydride generation Eco-indicator, 99 method, 419 Ecological/environmental risk assessment (ERA), 112

Index Ecosolvents. See Green solvents, 425 Ecotoxicity assessment, 209 passive sampling, 56 EDCs. See Endocrine disrupting chemicals EDL. See Electrodeless discharge lamp EDTA. See Ethylenediaminetetraacetic acid (EDTA) EINECS. See European Inventory of Existing Commercial Chemical Substances Electrochemical hydride generation (EcHG), 274 Electrochemical magneto immunosensing strategy, 156 Electrochemical speciation, 126–127 Electrochemical techniques, 275–278 anodic stripping voltammetry, 275–276 potentiometric sensors, 276–278 Electrochemistry sensing technology, advances in, 362 Electrodeless discharge lamp (EDL), 266 Electron capture detection (ECD), 130 Electro-osmotic flow (EOF), 280 Electrospray ionization (ESI), 332 Electrothermal Atomic Absorption Spectrometry (ETAAS), 268–269 atomizer, 268 matrix modification, 268–269 ELISAs. See Enzyme-linked immunosorbent assays EMEP, 399 measurements, 400 monitoring network of precipitation chemistry, 400–401 objective of, 400 Emerging contaminants, 140 Empore disk, 54 En score, in evaluation of laboratory results, 396 Endocrine disrupting chemicals (EDCs), 166 Endocrine disruptors, 200–201 Enteromorpha intestinalis, 105 Environmental analysis, total parameters in, 227–233 Environmental analytics, 223, 224 Environmental monitoring bioassay application in, 210 hot spots, identification of, 211–212 monitoring parameters, revision of, 214–216 polluted areas managed by specific areas, ranking of problems in, 212–214 toxic compounds, identification of, 210–211 legal regulations applicable to toxicity measurement, 201, 205–207 Environmental pollution extent assessment, chemical monitoring in, 190–192 Environmental Protection Agency (EPA), 142, 200, 227, 354, 390 Environmental quality standards (EQS), 59 Environmental samples, ecotoxicological classification of, 201, 207–210 Environmental water pollution, main sources of, 200 Enzyme-linked immunosorbent assays (ELISAs), 143, 144 for corticosteroids detection, 169 for heavy metals analysis, 150 EOF. See Electro-osmotic flow EOX. See Extractable organic halides EPA. See Environmental Protection Agency EQS. See Environmental quality standards Equilibrium sampling, 43–44, 47 Equilibrium sampling devices (ESDs), 84

479

Index Equilibrium sampling through membranes (ESTM), 83 ERA. See Ecological/environmental risk assessment; Estrogen receptor agonists ESDs. See Equilibrium sampling devices ESI. See Electrospray ionization ESTM. See Equilibrium sampling through membranes Estrogen receptor agonists (ERA), 56 Estrogenic substances, 333–334 Estrogens, immunochemical determination of, 166–168 ETAAS. See Electrothermal Atomic Absorption Spectrometry Ethylenediaminetetraacetic acid (EDTA), 25 Euphotic zone, 305 EUROCAT project, 211 Europe precipitation samples in, 401–409 collection of, 401–402 heavy metals and metalloids in precipitation, measurement of, 405–408 ions, pH, and conductivity in precipitation, measurements of, 402–405 POPs in precipitation using GC-MS, measurements of, 408–409 rural monitoring network in, 399–401 European Inventory of Existing Commercial Chemical Substances (EINECS), 141 European “Metropolis” project, 306 Event-controlled sampling, 4, 5 Exchange columns (Trap and Elute), 127 Excited state, 263 External QC, 395–396 Extractable organic halides (EOX), 228 Extractable organohalogens. See Extractable organic halides (EOX) Extraction solvent, 72

F F-AAS. See Flame-atomic absorption spectroscopy FAAS. See Flame atomic absorption spectrometry Fabrication controls, 57 FAS. See Fatty alcohol sulfates Fatty alcohol sulfates (FAS), 145 FDA. See Food and Drug Administration Fe. See Iron 55Fe. See Iron Fenamiphos, 28 Fenitrothion, 28, 31 FFF. See Field flow fractionation FIA. See Flow injection analysis Fiber-in-tube SPE (FIT-SPE), 72–73 Field blanks, 7–8 Field controls, 57 Field flow fractionation (FFF), 315 Field validation, 58–59 FI-ICP-ES. See Flow injection inductively coupled plasma-emission spectrometry Fission products (90Sr and 137Cs) determination, 246–248 FIT-SPE. See Fiber-in-tube SPE Flame atomic absorption spectrometry (FAAS), 266–268 background correction, 267–268 flame atomizer, 267 nebulizers, 267 radiation, source of, 266–267

Flame-atomic absorption spectroscopy (F-AAS), 405, 408 Flame atomic spectroscopy, 405 Flame atomizer, 267 Flat sheet Microporous membrane liquid–liquid extraction, 84 Flow injection analysis (FIA) methods, 281, 282, 327 Flow injection inductively coupled plasma-emission spectrometry (FI-ICP-ES) system, 127 Flow-weighted sampling. See Quantity-proportional sampling Fluorescence polarization immunoassay (FPIA), 146, 150 Fluorocarbon polymers, 13 Fluoroquinolones (FQs), detection of, 161–162 FMW. See Focused microwaves Focused microwaves (FMW), 454 Food and Drug Administration (FDA), 390 Fourier-transform ion cyclotron resonance instruments, 317 FPIA. See Fluorescence polarization immunoassay FQs. See Fluoroquinolones Freezing, water preservation method, 21 FS-MMLLE. See Flat sheet Microporous membrane liquid–liquid extraction Fucus, 112 Fucus vesiculosus, 105 Furanes, 30

G G immunoglobulins (IgG), 142 Galvanized steel, 13 Gas chromatograph coupled to an isotope ratio mass spectrometer (GCIRMS), 232 Gas chromatographic separation methods, 130 Gas chromatography (GC), 71, 309–311 with atomic emission detection (GC-AED), 224 -electron capture detection (GC-ECD), 86 improvements, 131 -mass spectrometry (GC-MS), 228 -mass spectroscopy (LC-MS), 316, 317 Gas-permeable membrane sensors, 278 GC. See Gas chromatography GC × GC, 311, 312, 314 GCI. See Green Chemistry Institute GCIRMS. See Gas chromatograph coupled to an isotope ratio mass spectrometer Gestagens, immunochemical determination of, 169 GF-AAS. See Graphite furnace atomic absorption spectrometry Glass containers, 13, 26 Gloves, 13 GLP. See Good Laboratory Practice Good Laboratory Practice (GLP), 193, 390, 391 Gracilaria verrucosa, 105 Gradient elution, 279 Graphite furnace atomic absorption spectrometry (GF-AAS), 125, 407–408 Gravimetric methods, 262 Gravity corers, 16 Green analytical chemistry, 70 characteristics of, 356 electrochemistry sensing technology, advances in, 362 history of, 354–355 implementation of, 355 miniaturization in, 362–363

480 Green analytical chemistry (Continued ) objective of, 355 principles of, 362 requirements for, 361 in sample pretreatment, 356 accelerated solvent extraction (ASE), 356–357 ILs, application of, 361 liquid-phase microextraction (LPME), 359–360 pressurized hot water extraction (PHWE), 360 single-drop microextraction (SDME), 359 solid-phase microextraction (SPME), 357–358 stir bar sorptive extraction (SBSE), 258 supercritical fluid extraction (SFE), 360–361 thin-film microextraction, 358–359 ultrasonic and microwave extraction, 357 Green Chemistry Institute (GCI), 354 Green chemistry, 354, 458 green analytical chemistry, 459–463 history, 458–459 Green solvents, 425 Griess method, 404 Ground water samplers, 14 Ground water sampling, 11 Groundwater monitoring, 191 Group speciation, 437

Index High-performance liquid chromatography tandem mass spectrometry (HPLC-MS/MS), 168 High-intensity focused ultrasound (HIFU), 230 High-intensity hollow cathode lamps (HI-HCL), 271 High-performance immunochromatographic (HPIAC) procedure, 147 High-resolution continuous source atomic absorption spectrometry (HR-CS AAS), 269–270 High-temperature precipitate digestion, 262 HI-HCL. See High-intensity hollow cathode lamps Hollow cathode lamp (HCL), 266 Hot spots, identification of, 211–212 HPIAC. See High-performance immunochromatographic HPLC. See High-performance liquid chromatography HPLC-MS/MS. See High performance liquid chromatography tandem mass spectrometry HR-CS AAS. See High-resolution continuous source atomic absorption spectrometry HS. See Headspace; Humic substances HS-SPME. See Headspace Humic substances (HS), 231 Hydrocarbons storage, 31 Hydrogels, 55 Hydrophobic organic compounds, passive sampling, 50 Hydrosphere, human impact on, 305 Hyphenation, of MMLLE, 84

H Hand-held open-mouth bottle sampler, 9 HCL. See Hollow cathode lamp Headspace (HS) techniques, 318 Headspace (HS-SPME), 358 Heavy metals and metalloids determination, 149–150 in precipitation, 405 cold vapor atomic fluorescence spectroscopy (CV-AFS), 408 flame-atomic absorption spectroscopy (F-AAS), 408 graphite furnace atomic absorption spectroscopy (GF-AAS), 407–408 inductively coupled plasma mass spectrometry (ICP-MS), 406–407 sample preparation, 405–406 Hediste diversicolor, 107 HELCOM. See Helsinki Commission Helsinki Commission (HELCOM), 201 Herbicides, detection of, 154–158 Hexavalent chromium Cr(VI), 26 Hg speciation, 129 DMHg, analytical methods for, 130 handling and storage, of samples, 129–130 Hg(0), analytical methods for, 130 Hg-R, analytical methods for, 130 Hg-T, analytical methods for, 130 MMHg, analytical methods for, 130–132 modeling of, 132 Hg(0), analytical methods for, 130 Hg-R, analytical methods for, 130 Hg-T, analytical methods for, 130 Hierarchical clustering, 371 HIFU. See High-intensity focused ultrasound High-performance liquid chromatography (HPLC), 56, 73, 127, 279, 311

I IA. See Immunoaffinity IC. See Ion chromatography ICE. See Integrated Control of Effluents ICES. See International Council for the Exploration of the Sea ICP-AES. See Inductively coupled plasma atomic emission spectrometry ICP-MS. See Inductively coupled plasma mass spectrometry ICP-OES. See Inductively coupled plasma optical emission spectroscopy IgG. See G immunoglobulins ILCs. See Interlaboratory comparisons ILs. See Ionic liquids Immunoaffinity (IA) sorbents, 324 Immunochemical analytical methods, for monitoring aquatic environment, 140–142 industrial contaminants, determination of, 142 bisphenol A, 150–151 heavy metals and metalloids, 149–150 organohalogenated compounds, 147–149 polycyclic aromatic hydrocarbons, 142–145 surfactants, 145–147 for pesticides, 151–152 herbicides and plant growth regulators, 154–158 insecticides, 152–154 pharmaceutical and personal care products, 158 antibiotics, 158–166 steroid hormones, 166–169 Immunosensors, 142 In situ speciation, in aquatic system, 123–125 In-tube extraction (ITEX), 73 In-tube SPME, 358 Indicator electrode, 277 Individual speciation, 438

481

Index Indomethacin, detection of, 165, 166 Indophenol blue method, 404–405 Inductively coupled plasma atomic emission spectrometry (ICP-AES), 233 Inductively coupled plasma mass spectrometry (ICP-MS), 125, 132, 224, 406–407 Inductively coupled plasma optical emission spectroscopy (ICP-OES), 224, 270–271 instrumentation, 270 nebulizers and spray chambers, 271 optics and detectors, 271 plasma torch, 270 RF generators, 270–271 Inductively coupled plasma-mass spectrometry, 272–273, 318 instrumentation, 272–273 ion detectors, 273 mass analyzers, 273 Industrial contaminants, determination of, 142 bisphenol A, 150–151 heavy metals and metalloids, 149–150 organohalogenated compounds, 147–149 polycyclic aromatic hydrocarbons, 142–145 surfactants, 145–147 Injector, 270 Inorganic compounds determination, water samples preservation and storage for, 19–22 Inorganic constituents analytical techniques, 261 gravimetric measurements, 262 spectrophotometric technique, 263 titrimetric measurement, 262–263 characteristics of, 260 classification, of aquatic ecosystem, 260–261 determination of, 282 dissolved gases determination methods, 290 ion determination methods, 286 metals determination methods, 291–294 non-metallic substances determination methods, 286–290 nutrient determination methods, 283–285 using IC, 285 Inorganic pesticides, 28 Inorganic sampling, 13 Insecticides, detection of, 152–154 Inside-needle SPE, 73 Integrated Control of Effluents (ICE), 201 Interlaboratory comparisons (ILCs), 390, 391, 396 Internal QC, 395 International Council for the Exploration of the Sea (ICES), 57 International Odra Project (IOP), 210 International Organization for Standardization (ISO), 143 International Union of Applied and Pure Chemistry (IUPAC), 354 speciation analysis definition, 224 Ion chromatography (IC), 127, 278–280, 309, 315, 404 Ion detectors, 273 Ion determination methods, 286 Ion trap mass spectrometers, 316 Ionic liquids (ILs), 361, 452–453 Ionization techniques, 317 Ions, in precipitation samples, 402–403

Ion-selective electrodes (ISEs), 263 glass membranes, 277 potentiometric dissolved gas sensors, types of, 278 IOP. See International Odra Project Iron, 122–123 coprecipitation of, in natural water with iron hydroxide, 243 determination, 242, 243, 244 mineralization, separation, and electrolysis in aquatic sediments and biota samples, 243–244 separation and determination, 243 speciation, 13, 122 electrochemical speciation, 126–127 hyphenated methods chemiluminescence and colorimetric reactions, 128 chromatography, 127–128 exchange columns, 127 in situ speciation, in aquatic system, 123–125 sample preservation and storage, 126 sampling, 125 ISEs. See Ion-selective electrodes ISO. See International Organization for Standardization ISO Guide 9000:2000, 391 ISO/IEC 17025:2005, 391 Isocratic elution, 279 ITEX. See In-tube extraction IUPAC. See International Union of Applied and Pure Chemistry

J Judgemental sampling pattern, 5

K 40K determination. See Potassium determination Kin ExA™ 3000, 150 Kinetic sampling, 44–45, 47 Kjeldahl nitrogen, 285 Kremmer sampler, 14

L Labs-on-a-chip, 363 LA-ICP-MS. See Laser ablation inductively coupled plasma mass spectrometry LAS. See Linear alkylbenzene sulfonates Laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS), 125 Laser-excited AFS (LEAFS), 272 Laser-induced atomic fluorescence spectrometry (LIF), 272 Latent variables, 380 LC. See Liquid chromatography LC × LC, 313, 314 LCA. See Life cycle assessment LC-MS. See Liquid chromatography-mass spectroscopy LDPE. See Low-density polyethylene Lead determination coprecipitation of, in natural water with manganese dioxide, 249–250 radiochemical methods, 249 radionuclide activity determination, 253–255 separation and determination, 251

482 LEAFS. See Laser-excited AFS Legal regulations, to measure toxicity, 201, 205–207 LIF. See Laser-induced atomic fluorescence spectrometry Life cycle assessment (LCA), 427–428, 460 general idea, 413–414 methodology, 414–424 goal and scope, 415–416 life cycle impact assessment, 418–421 life cycle interpretation and application, 421–424 life cycle inventory analysis, 416–418 for solvent use in analytical protocols, 424–427 Limits of detection (LODs) for trace metal species, in aquatic samples, 124 Linear alkylbenzene sulfonates (LAS), 145 Liquid chromatography (LC), 72, 131–132, 311–313 Liquid chromatography-mass spectroscopy (LC-MS), 316, 337 Liquid extraction techniques, 448 Liquid membrane based techniques microporous membrane liquid–liquid extraction, 84–87 supported liquid membrane (SLM) extraction, 79–84 two-phase HF-LPME, 87–88 Liquid–liquid extraction (LLE), 31, 32, 321 Liquid-phase microextraction (LPME), 71, 359–360 Littrow prism, 269 Liza aurata, 113 LLE. See Liquid–liquid extraction LMWOM. See Low-molecular-weight organic molecules Loadings plots, 381 LODs. See Limits of detection LOQ. See Quantification limit Low-density polyethylene (LDPE), 48, 75 Low-molecular-weight organic molecules (LMWOM), 30, 31 LPME. See Liquid-phase microextraction L’vov platform, 268 Lyophilization, 31

M Macoma balthica, 107 Macrolides, detection of, 165 MAE. See Microwave-assisted extractions MALDI-MS. See Matrix-assisted laser-desorption/ ionization-mass spectroscopy MAME. See Microwave-assisted micellar extraction Manganese speciation, 122–123 electrochemical speciation, 126–127 hyphenated methods chemiluminescence and colorimetric reactions, 128 chromatography, 127–128 exchange columns, 127 in situ speciation, in aquatic system, 123–125 sample preservation and storage, 126 sampling, 125 Manifest variables, 380 Manual corers, 12, 16 Manual surface water samplers, 13–14 Marine strategy directive, 141 Marsh reaction, 274 MASE. See Membrane-assisted solvent extraction Mass analyzers, 273 Mass spectrometric techniques, 272–273

Index inductively coupled plasma-mass spectrometry, 272–273 Mass spectroscopy (MS) detectors, 311 Matrix modification, 268–269 Matrix solid-phase dispersion, 448–448 Matrix-assisted laser-desorption/ionization-mass spectroscopy (MALDI-MS) analysis, 361 MCGC. See Multicapillary GC MEC. See Microwave-enhanced chemistry Medium pressure liquid extraction, 448 MEKC. See Micellar electrokinetic chromatography Membrane electrode, 277 Membrane enclosed sorptive coating (MESCO) sampler, 46, 48 Membrane extraction with sorbent interface (MESI), 76–77, 320 Membrane inlet (introduction) mass spectrometry (MIMS), 76, 320 Membrane morphology, information on, 446–447 Membrane permeability, 46 Membrane techniques, application of, 442 membrane extraction, 445–448 Membrane/water partition coefficient, 46 Membrane-assisted solvent extraction (MASE), 78–79 MEPS. See Microextraction in packed syringe Mercury thiocyanate-iron method, 405 Mercury, speciation analysis, 26 MESCO. See Membrane enclosed sorptive coating MESI. See Membrane extraction with sorbent interface Metallothioneins (MTs), 113–114, 150 Metals, passive sampling, 55 Metals determination methods, 291–294 Methyl tertiary butyl ether (MTBE), 427 Methyl-trimethoxysilane (MTMS), 313 Micellar electrokinetic chromatography (MEKC), 281, 315 Micro total analysis systems (μTAS), 363 Microbics Corporation. See AZUR Environmental Microbioassays, 198 Microextraction in packed syringe (MEPS), 73 Micro-immune-supported liquid membrane assay (m-ISLMA), 156 Microporous membrane liquid–liquid extraction (MMLLE), 84–87 automated flowing MMLLE off-line systems, 84, 86–87 on-line systems, 84–85 syringe device extraction, 85–86 hyphenation, 84 miniaturization, 84 principle, 84 Microporous membranes, 46 Microtox, 196 Microwave heating, 454 Microwave-assisted extractions (MAE), 357, 454 Microwave-assisted micellar extraction (MAME), 455 Microwave-assisted mineralization of natural waters, 99–100 Microwave-enhanced chemistry (MEC), 454–455 MIMS. See Membrane inlet (introduction) mass spectrometry Mineralization of biota, 251 of sediment, 251 of suspended matter, 250–251

483

Index Miniaturization in analytical chemistry methods, 362–363 goal, 363 objectives, 362 of MMLLE, 84 Miniaturized liquid-phase extraction techniques, 70–72 background, 71 continuous-flow microextraction (CFME), 71–72 dispersive liquid–liquid microextraction (DLLME), 72 dynamic liquid-phase microextraction (DLPME), 71 Miniaturized nonmembrane-based extraction techniques miniaturized liquid-phase extraction techniques, 70–72 miniaturized SPE techniques, 72–73 solid-phase microextraction, 73–75 stir bar sorptive extraction, 75 Miniaturized SPE techniques, 72–73 fiber-in-tube SPE (FIT-SPE), 72–73 inside-needle SPE, 73 microextraction in packed syringe (MEPS), 73 MIPs. See Molecularly imprinted polymers MMHg. See Monomethylmercury MMLLE. See Microporous membrane liquid–liquid extraction Mn speciation. See Manganese speciation Molar absorptivity, 264 Molecular spectrophotometry, 264 Molecularly imprinted polymers (MIPs), 324, 325 Monitoring parameters, revision of, 214–216 Monitors, 434 Monomethylmercury (MMHg), 129 analytical methods for, 130–132 derivatization and validation, 130–131 detection methods, 132 extraction procedures, 130 gas chromatographic separation methods, 130 GC improvements, 131 liquid chromatographic separation methods, 131–132 MRM. See Multiple reaction-monitoring MS. See Mass spectroscopy MTBE. See Methyl tertiary butyl ether Mtethyl mercury, 26 MTMS. See Methyl-trimethoxysilane MTs. See Metallothioneins m-ISLMA. See Micro-immune-supported liquid membrane assay μTAS. See Micro total analysis systems Multicapillary GC (MCGC), 131 Multidimentional high-performance liquid chromatography, 313 Multi-IAC. See Multi-immunoaffinity chromatography Multi-immunoaffinity chromatography (multi-IAC), 168 Multiple reaction-monitoring (MRM) mode, 316 Mussels, 57 Mytilus edulis, 57 Mytilus galloprovincialis, 112, 114 Mytilus, 106

N Nafion, 50 Natural and transuranic alpha radionuclides determination, 249–256

Natural water, 95 classification system for, 208 microwave-assisted mineralization, 99–100 Near-infrared spectroscopy, 233 Nebulizers, 267 and Spray chambers, 271 Nephelometry, 265 Nernst equation, 277 Neutron activation products (55Fe and 63Ni) determination, 242–246 63Ni determination. See Nickel determination Nickel determination coprecipitation of, in natural water with hydroxide, 245–246 determination, 242–246 mineralization, separation, and electrolysis of, in aquatic sediments and biota samples, 246 separation and determination, 244–245 Nitrate griess method for, 404 Nitric acid, 25 Nitrofurans, detection of, 166 Nitrofurantoin, detection of, 165, 166 Nitrogen, 260. See also Nutrients Nitrous oxide–acetylene flame, 267 Nonchromatographic techniques, for organic and organometallic pollutants, 326–328 Nonhierarchical clustering, 371 Noninorganic surfactants (NS), 31 Nonionic surfactants, 30, 145 Non-metallic substances determination methods, 286–290 Nonporous membranes, 46 Nonporous polymeric membranes based techniques, 75–76 membrane-assisted solvent extraction, 78–79 membrane extraction with sorbent interface, 76–77 membrane inlet (introduction) mass spectrometry (MIMS), 76 Nonylphenol (NP), 145 Normal phase (NP) separations, 313 Normal phase HPLC (NP-HPLC) mobile phases, 313 Normalization, 419 NP. See Nonylphenol; Normal phase NP-HPLC. See Normal phase HPLC NS. See Noninorganic surfactants Nuclear weapons, 242 Nutrient determination methods, 283–285 using IC, 285 Nutrients, 260 Nylon, 13

O OC. See Organic carbon; Organochlorine Octa-BDE, 148 Octylphenol (OP), 145 Off-line SPE, 321 Off-line systems, of HF-MMLLE, 84, 86–87 nonautomated, nonflowing design, 86–87 On-column injection, 309 On-line ESy-GC instrument, 85 On-line SFE, 451 On-line SPE, 323, 324, 331 On-line SPE-GC, 323 On-line SPE-GC-HPLC, 323

484 On-line SPE-LC-MS methods versus biosensors, 328 On-line systems, of MMLLE, 84–85 OP. See Octylphenol; Organophosphorus Optical SPR immunosensors, 151 Optical waveguide lightmode spectroscopy (OWLS), 158 Orchestia gammarellus, 114 Organic and organometallic pollutants, 306 classification, 305–306 interactions, 305 Organic and organometallic pollutants, analytical methods for analyzing, 306 analyte derivatization, 325–326 chromatographic analysis, sample preparation for, 318–325 classification, 306–307 detection techniques, 315 Fourier-transform ion cyclotron resonance instruments, 317 inductively coupled plasma-mass spectrometry, 318 ion trap mass spectrometers, 316 ionization techniques, 317 quadrupole mass spectrometers, 316 time-of-flight (TOF) instruments, 317 triple quadrupole mass spectrometers, 316–317 nonchromatographic techniques, 326–328 separation techniques, 309 capillary electrophoresis, 313–315 gas chromatography, 309–311 liquid chromatography, 311–313 micellar electrokinetic chromatography (MEKC), 315 size exclusion chromatography, 315 Organic carbon (OC) oxidation of, 225 Organic compounds determination, water samples preservations and storage for, 27–32 Organic polymers, 12 Organic sampling, 13 Organochlorine (OC), 151 Organogermanium compounds, 339–340 Organohalogenated compounds, 147–149 Organolead compounds, 339 Organometallic compounds, passive sampling, 54–55 Organometallic species organogermanium compounds, 339–340 organolead compounds, 339 organoselenium compounds, 340–342 organotin (OT) compounds, 335–338 Organophosphates, 28 Organophosphorus (OP) insecticides, 151 Organoselenium compounds, 340–342 Organotin (OT) compounds, 335–338 OT. See Organotin OWLS. See Optical waveguide lightmode spectroscopy Oxidative stress, 112–113 Ozonation. See Ozone oxidation Ozone oxidation, 98–99

P Pachygrapsus marmoratus, 114 Paclitaxel, detection of, 166 PAHs. See Polycyclic aromatic hydrocarbons; Polynuclear aromatic hydrocarbons Particulate matter (PM), 8

Index Passive sampling, 41–42 affecting factors, 47–48 applications, 50 in algal toxins, 55–56 in biomonitoring, 57 in ecotoxicity assessment, 56 in hydrophobic organic compounds, 50 in metals, 55 in organometallic compounds, 54–55 in polar organic compounds, 50, 54 in volatile organic compounds, 54 biofouling, 48–50 concept of, 42–43 data validation, 57–59 equilibrium sampling, 43–44 future trends, 60–61 kinetic sampling, 44–45 quality assurance, 57 quality control, 57 in regulatory monitoring, 59–60 samplers, 14–15, 51–53 diffusion barrier, 45–46 modeling and calibration, 46–47 sorption phase, 45 Pasteurization, water preservation method, 21 210Pb determination. See Lead determination PBDEs. See Polybrominated diphenylethers PCA. See Principal component analysis PCA with multiple linear regression analysis (PCAMLRA), 383 advantage of, 384 methodology of, 384 PCAMLRA. See PCA with multiple linear regression analysis PCB RaPID Assay®, 147 PCBs. See Polychlorinated biphenyls PCCPs. See Personal care and cosmetic products PCDDs. See Polychlorinated dibenzo-para-dioxins PCDFs. See Polychlorinated dibenzofurans PDMS. See Polydimethyl-siloxane PE containers. See Polyethylene containers PEEK. See Polyetheretherketone Pelagic species, 108–109 Penta-BDE, 148 Pentavalent arsenate As(V), 25 Perfluorinated sulfonates, 333 Perfluorooctane sulfonate (PFOS), 333 Performance parameters, 393 Performance reference compounds (PRCs), 47 Permeable polymeric membrane, 46 Permeation-based samplers, 46 Perna, 106 Persistent organic pollutants (POPs) measurement in precipitation, 408–409 Personal care and cosmetic products (PCCPs), 305, 334 Pesticides, 330 immunochemical methods for, 151–152 herbicides and plant growth regulators, 154–158 insecticides, 152–154 sample preservation and storage, 28, 29 PFE. See Pressurized fluid extraction PFOS. See Perfluorooctane sulfonate pH in precipitation, determination of, 403 Pharmaceutical and personal care products (PPCPs), immunochemical determination of, 158

Index antibiotics, 158–160, 165–166 amphenicols, 162–163 b-lactams, 164 fluoroquinolones, 161–162 macrolides, 165 sulfonamides, 160–161 tetracyclines, 163–164 steroid hormones, 166 androgens, 168–169 corticosteroids, 169 estrogens, 166–168 gestagens, 169 Pharmaceuticals, 334 Phenanthrene, 58, 143, 144 Phenol index, 227 Phenols, 330–331 sample preservation and storage, 28, 29 Phosphorus, 260. See also Nutrients Photometer, 264 Photons, 263 Phragmites, 105 PHWE. See Pressurized hot water extraction Physical speciation, 224 Piezoelectric quartz crystal (PQC) immunosensor, 147 PIME. See Pulse introduction (flow injection-type) membrane extraction Plants, contaminants accumulation and partitioning, 110 Plasma torch, 270 Plastics, 13 Plutonium determination activity determination, 256 coprecipitation of, in natural water with manganese dioxide, 249–250 radiochemical methods, 249 radionuclide activity determination, 253–255 radionuclide activity measurement, 253 separation, purification, and electrolysis of, 252 PM. See Particulate matter Pneumatic nebulizers, 267 210Po determination. See Polonium determination POCIS. See Polar Organic Chemical Integrative Sampler Polar Organic Chemical Integrative Sampler (POCIS), 54, 56 Polar organic compounds, passive sampling, 50, 54 Pollutants, applications to different classes of, 329 estrogenic substances, 333–334 organometallic species organogermanium compounds, 339–340 organolead compounds, 339 organoselenium compounds, 340–342 organotin (OT) compounds, 335–338 personal care and cosmetic products (PCCPs), 334 pesticides, 330 pharmaceuticals, 334 phenols, 330–331 solvents and volatile compounds, 329–330 sulfonates, 333 surfactants, 331–333 Polluted areas managed by specific areas, ranking of problems in, 212–214 Polonium determination coprecipitation of, in natural water with manganese dioxide, 249–250 radiochemical methods, 249 radionuclide activity determination, 253–255

485 radionuclide activity measurement, 253 separation and determination, 251 Polyacrylamide gel, 125 Polybrominated diphenylethers (PBDEs), 147, 148 Polychlorinated biphenyls (PCBs), 86, 147 sample preservation and storage, 28, 29 Polychlorinated dibenzofurans (PCDFs), 147, 148 Polychlorinated dibenzo-para-dioxins (PCDDs), 147, 148 Polycyclic aromatic hydrocarbons (PAHs), 32, 71, 142–145, 309 Polydimethyl-siloxane (PDMS), 321 Polyetheretherketone (PEEK), 71 Polyethersulfone, 49 Polyethylene containers, 13, 26 Polymers, 45 Polynuclear aromatic hydrocarbons (PAHs), 28, 30–31, 45 Polypropylene, 13 Polytetrafluoroethylene (PTFE), 26, 79, 276 Polyvinyl chloride, 13 Polyvinylidine difluoride (PVDF), 79 POPs. See Persistent organic pollutants Posidonia, 105 Posidonia oceanica, 105 Potassium determination, 242 Potentiometric sensors, 277 POX. See Purgeable organic halides PPCPs. See Pharmaceutical and personal care products PQC. See Piezoelectric quartz crystal PRCs. See Performance reference compounds Precipitation quality measurement, analytical procedures for used within EMEP monitoring program data quality control, 409–410 future perspectives, 410–411 precipitation samples, in Europe, 401–409 rural monitoring network in Europe, scope of, 399–401 Precipitation samples, in Europe, 401 collection of, 401–402 conductivity, of precipitation samples, 403–404 flame atomic spectroscopy, determination by, 405 heavy metals and metalloids in precipitation, measurement of, 405 cold vapor atomic fluorescence spectroscopy (CV-AFS), 408 flame-atomic absorption spectroscopy (F-AAS), 408 graphite furnace atomic absorption spectroscopy (GF-AAS), 407–408 inductively coupled plasma mass spectrometry (ICP-MS), 406–407 sample preparation, 405–406 ion chromatography, 404 ions, in precipitation samples, 402–403 pH in precipitation, determination of, 403 POPs in precipitation using GC-MS, measurements of, 408–409 spectrophotometry, 404–405 Preservation and storage of water samples for inorganic compounds determination, 19–22 for organic compounds determination, 27–32 for speciation analysis of metals, 22–25 arsenic, 25 chromium, 26 mercury, 26 selenium, 26–27 tin, 27

486 Pressurized fluid extraction (PFE). See Accelerated solvent extraction Pressurized hot water extraction (PHWE), 360 Pressurized MAE, 454 Primordial radionuclide (40K) determination, 242 Principal component analysis (PCA), 373 case study (Struma River), 382–383 theoretical principles, 380–382 Proficiency testing (PT) scheme, 390, 391 Programmable temperature vaporizer (PTV) injectors, 309 Propanil, detection of, 156 Prorocentrum lima, 56 PT. See Proficiency testing PTFE. See Polytetrafluoroethylene PTV. See Programmable temperature vaporizer 238Pu determination. See Plutonium determination 239+240Pu determination. See Plutonium determination 241Pu determination. See Plutonium determination Pulse introduction (flow injection-type) membrane extraction (PIME), 77 Pumps, 14 Purgeable organic halides (POX), 228 Purified water, 95 PVDF. See Polyvinylidine difluoride Pyrethroids, 28

Q QA/QC. See Quality assurance/quality control QM. See Quality management Quadrupole mass spectrometers, 316 Quadrupoles, 273 Quality assurance/quality control, 7, 8, 57, 389–390 of analytical results, 391–393 monitoring of, 394–396 traceability, 394 validation of analytical procedures, 393–394 quality in chemical measurements, 390–391 Quality management (QM), 390, 392 Quantification limit (LOQ), 8 Quantity-proportional sampling, 4 Quantum theory, 263

R 222

Ra determination. See Radium determination Ra determination. See Radium determination Radiation source, 266–267 Radio frequency generator (RF generator), 270–271 Radiolead determination, radiochemical methods, 249 coprecipitation of, in natural water with manganese dioxide, 249–250 radionuclide activity measurement, 253–255 Radionuclides determination, 242 222Ra in water, 249 226Ra in water, 248–249 fission products (90Sr and 137Cs), 246–248 natural and transuranic alpha radionuclides (210Po, 234U, 235U, 238U, 238Pu, 239+240Pu, and 241Pu), 249–256 neutron activation products (55Fe and 63Ni), 242–246 primordial radionuclide (40K), 242 Radium determination, 248–249 Random sampling pattern, 5 226

Index RBMP. See River Basin Management Plan R-Biopharm GmbH, 163 R-charts, 395 Reagent blanks, 57 Reagent-free ion chromatography (RF-IC), 232, 233 Receptor modeling case study (Struma River), 385 theoretical principles, 383–384 Reference materials (RMs), 395 Regulatory monitoring, passive sampling in, 59–60 Relative standard deviation (RSD) of heavy metals, in 2006, 411 of major ions in laboratory intercomparison, in 2005, 410 Replicate samples, 8 Retention time locking (RTL), 330 Reversed phase HPLC (RP-HPLC), 313 RF generator. See Radio frequency generator RF-IC. See Reagent-free ion chromatography Rhizoclonium tortuosum, 112 RIANA. See River ANAlyzer RIDASCREEN®, 163 River ANAlyzer (RIANA), 151, 157, 160 River Basin Management Plan (RBMP), 141 RMs. See Reference materials Royal Society of Chemistry, 354 RP-HPLC. See Reversed phase HPLC RSD. See Relative standard deviation RTL. See Retention time locking Rural monitoring network, in Europe, 399–401 Ruttner sampler, 10, 14

S Sample collection strategies, 1–2 general considerations, 2–5 samples types composite sample, 3–4 discrete sample, 3 sampling patterns, 5 sampling equipment automatic water sampling systems, 14 compatibility of sampler material, 12–13 ground water samplers, 14 manual surface water samplers, 13–14 passive samplers, 14–15 sediment samplers, 15–16 traditional techniques, 13 sampling-related uncertainty, 5–8 sediments samples, 11–12 water samples, 3–4, 8–11 Sample size, 8 Sampler material, compatibility with water samples, 12–13 Sampler recovery spikes, 57 Samples preparation, for analysis, 431 analytical data, types of, 434–435 analytical procedure, stages of, 440–442 green chemistry, 458 green analytical chemistry, 459–463 history, 458–459 ionic liquids, 452–453 matrix solid-phase dispersion, 448–448 membrane techniques, application of, 442 membrane extraction, 445–448

Index microwave-enhanced chemistry (MEC), 454–455 new methodological developments in, 442–444 speciation analytics, 435 chemical speciation, 437–439 physical speciation, 437 supercritical fluid extraction, 449–451 surfactant micelles, unique phase separation behavior of, 451–452 trace element analysis, problems associated with, 439–440 ultrasound (US) application in, 455–458 Sampling patterns, 5, 6 Sampling rate, 45, 46 Sampling uncertainty, 5–8 SAs. See Sulfonamides SBME. See Solvent bar microextraction SBSE. See Stir bar sorptive extraction SC. See Stripping chronopotentiometry Score plot, 381 Scott chamber design, 271 Scree plot, 382 Screening speciation, 437 Scrobicularia plana, 107 SDME. See Single-drop microextraction SDS. See Sodium dodecyl sulfate Sediment sample collection, 11–12 Sediment samplers, 15–16 Sediment, mineralization of, 251 Segmented flow analysis (SFA), 281 Selected ion monitoring (SIM), 86 Selenium, 436 speciation analysis, 26–27 Self-organizing maps (SOM) advantage of, 376 architecture, 376 case study (Struma River), 377–379 theoretical principles, 376–377 Semipermeable membrane device (SPMD), 46, 49, 54, 56, 58 Sensors, 327 Separation techniques, 278–281 capillary electrophoresis, 280–281 ion chromatography, 278–280 for organic and organometallic pollutants, 309 capillary electrophoresis, 313–315 gas chromatography, 309–311 liquid chromatography, 311–313 micellar electrokinetic chromatography (MEKC), 315 size exclusion chromatography, 315 Sequential injection analysis (SIA), 145–146 Sequential injection/flow injection analysis (SIA/FIA) system, 230–231 SETAC. See Society of Environmental Toxicology and Chemistry SFA. See Segmented flow analysis SFE. See Supercritical fluid extraction SIA. See Sequential injection analysis SIA/FIA. See Sequential injection/flow injection analysis SID-MS. See Speciated isotope dilution mass spectrometry Silica, 285 Silica base material, 313 Silicon, 261. See also Nutrients

487 Silicone, 13 Silicone rubber, 45 Silicone strip sampler, 48 SIM. See Selected ion monitoring SimaPro, 416–417, 419 Single linkage method, 372 Single-drop microextraction (SDME), 71, 359 Size exclusion chromatography, 315 SLM. See Supported liquid membrane Slotted tube atom traps (STATs), 267 Small-depths samplers, 13–14 SME. See Solvent microextraction Smith–Hieftje background correction, 268 Society of Environmental Toxicology and Chemistry (SETAC), 413 Sodium dodecyl sulfate (SDS), 145 Solid-phase adsorption toxin tracking (SPATT) bags, 55 Solid-phase dynamic extraction (SPDE), 73 Solid-phase extraction (SPE), 31, 32, 321, 331 Solid-phase microextraction (SPME) sampler, 31, 32, 46, 55, 58, 73–75, 274, 320, 357–358 applications, recent trends in, 74–75 calibration in, 74 Solid-phase microextraction capillary gas chromatography (SPME-GC), 131 Solvent bar microextraction (SBME), 87 Solvent microextraction (SME), 71 Solvents and volatile compounds, 329–330 SOM. See Self-organizing maps Sorption, 27 Sorption phase, 45 Sorption phase-water partition coefficient, 43, 44 Spartina, 105 SPATT bags. See Solid-phase adsorption toxin tracking bags SPC. See Statistical process control SPCs. See Sulfophenyl carboxylates SPDE. See Solid-phase dynamic extraction SPE. See Solid phase extraction Speciated isotope dilution mass spectrometry (SID-MS), 132 Speciation analysis, 439 analytics, 121, 435 chemical speciation, 437–439 physical speciation, 437 Cr, Fe, Mn, and As speciation, 122–127 Hg speciation, 129–132 definition of, 224 of metals, 22–25 arsenic, 25 chromium, 26 mercury, 26 selenium, 26–27 tin, 27 Spectinomycin, detection of, 166 Spectrophotometry, 263, 264, 404–405 griess method, for nitrate, 404 indophenol blue method, for ammonium, 404–405 mercury thiocyanate-iron method, for chloride, 405 on molecular absorption radiation ultraviolet-visible spectroscopy, 263 Split/splitless injection, 309 SPM. See Suspended particulate matter SPMD sampler. See Semipermeable membrane device

488 SPME. See Solid-phase microextraction SPME-GC. See Solid-phase microextraction capillary gas chromatography Spoons/scoops, as sediment samplers, 11, 15 Spot water samples, 42, 59 SPR. See Surface plasmon resonance Spray chambers nebulizers and, 271 SQC. See Statistical quality control 90Sr determination. See Strontium determination Stabilization procedures, 20, 21, 23–25 Stabilized temperature platform furnace (STPF), 268 Stainless steel, 242 STATs. See Slotted tube atom traps Stationary phase technology, 313 Statistical process control (SPC), 395 Statistical quality control (SQC), 395 Steroid hormones, immunochemical determination of, 166 androgens, 168–169 corticosteroids, 169 estrogens, 166–168 gestagens, 169 Stir bar sorptive extraction (SBSE), 75, 258 development, 75 modes of operation, 75 STPF. See Stabilized temperature platform furnace Stripping chronopotentiometry (SC), 126 Strontium determination, 246, 247–248 activity calculation, 248 separation by adsorption on AMP, 246–247 Styrenedivinylbenzene copolymer, 278 Sulfonamides (SAs), detection of, 160–161 Sulfonates, 333 Sulfophenyl carboxylates (SPCs), 145, 333 Supercritical fluid extraction (SFE), 360–361, 449–451 Supervised (learning) methods, 370 Supported liquid membrane (SLM) extraction, 79–84 equilibrium sampling through, 83–84 principle, 79 selectivity, 83 transport mechanism, 81 diffusive transport, 81–82 facilitated transport, 82 unit and system configuration, 79–81 Surface plasmon resonance (SPR), 144 SPR Biacore sensor, 146 Surface water monitoring, 190–191 Surface water sampling, 9–11, 13 Surfactant micelles, unique phase separation behavior of, 451–452 Surfactants, 145–147, 331–333 Suspended matter, mineralization of, 250–251 Suspended particulate matter (SPM), 107 Sustainable development, into analytical practice goals of, 353 green analytical chemistry characteristics of, 356 electrochemistry sensing technology, advances in, 362 greener separation techniques, 361–362 history of, 354–355 implementation of, 355 miniaturization in, 362–363 in sample pretreatment, 356–361

Index SWIFT-WFD project, 59 Swiss Center for Electronics and Microtechnology (CSEM), 161 Synthetic organic pesticides, 28 Syringe device extraction, of MMLLE, 85–86 Systematic sampling pattern, 5

T Tank exposure studies, 47 Target compounds, methods to minimize loss from water samples, 20 TBTs. See Trisubstituted organotins TC. See Total carbon TCDD. See 2,3,7,8-Tetrachlorodibenzo-p-dioxin TCs. See Tetracyclines TDC. See Total dissolved carbon TDN. See Total dissolved nitrogen TECP. See Thermal extraction cone penetrometry probe 2,3,7,8-Tetrachlorodibenzo-p-dioxin (TCDD), 148 Tetractenos glaber, 111 Tetracyclines (TCs), detection of, 163–164 TH. See Total hydrocarbons Thermal desorber, 462 Thermal extraction cone penetrometry probe (TECP), 462 Thermal ionization mass spectrometry (TIMS), 242 THGAs. See Transversal heated graphite atomizers Thief samplers, 14 TIMS. See Thermal ionization mass spectrometry Thin-film microextraction, 358–359 304-grade stainless steel, 13 316-grade stainless steel, 13 Tigriopus brevicornis, 114 Time of flight (TOF), 273, 317 Time-proportional sampling, 4 Time-resolved fluoro-immunoassay (TR-FIA), 157 Time-weighted average (TWA) sampling, 42, 44, 45 Tin, speciation analysis, 27 Titration, 263 Titration error, 263 Titrimetric measurement, 262–263 TOC. See Total organic carbon TOF. See Time of flight Total carbon (TC), 192, 233 fractions in liquid and solid samples, 226 Total dissolved carbon (TDC), 233 Total dissolved nitrogen (TDN), 233 Total hydrocarbons (TH) parameters and techniques, used for determination of, 227 Total inorganic mercury, 231 Total organic carbon (TOC), 192, 225–227 definition of, 225 Total organic halides (TOX), 228, 232 Total parameters for evaluation of xenobiotics, in environment, 223 biochemical oxygen demand (BOD), 224–225 chemical oxygen demand (COD), 225 in environmental analysis, 227–233 total organic carbon (TOC), 225–227 Total sulfur (TS), 233 Total volatile organic carbon (TVOC), 228 Total volatile organic halogen (TVOX), 232 TOX. See Total organic halides

489

Index Toxic compounds, identification of, 210–211 Toxicity tests, importance of, 192–195 Toxkit tests, 195–199 Trace element analysis, 261, 439–440 Trace metal species in aquatic systems, concentration levels of, 122 Traditional techniques, 13–14 Transversal heated graphite atomizers (THGAs), 268 TR-FIA. See Time-resolved fluoro-immunoassay Tributyltin compounds, 335 Trifluralin, 158 Triple quadrupole mass spectrometers, 316–317 Trisubstituted organotins (TBTs), 27 Triton X, 145 Trivalent arsenite As(III), 25 Trivalent chromium Cr(III), 26 TS. See Total sulfur Tube-type samplers, 46 Turbidimetry, 265 TVOC. See Total volatile organic carbon TVOX. See Total volatile organic halogen TWA. See Time-weighted average Twisters, 75 2D-GC-MS, 330 Two-phase HF-LPME, 87–88 automation, 88 development, 87

U 234

U determination. See Uranium determination U determination. See Uranium determination 238U determination. See Uranium determination Ultra performance liquid chromatography (UPLC), 141, 313, 335 Ultrasonic extraction, 357 Ultrasound (US) application, in sample preparation process, 455–458 Ultraviolet photo-oxidation, 97–98 Ultraviolet-visible (UV-VIS), 263 Ulva, 105 Uncertainty, of analytical results, 5–8 Unsupervised multivariate statistical methods, 370 UPLC. See Ultra performance liquid chromatography Uranium determination coprecipitation of, in natural water with manganese dioxide, 249–250 radiochemical methods, 249 radionuclide activity determination, 253–255 radionuclide activity measurement, 253 separation, purification, and electrolysis, 252–253 US. See Ultrasound US Presidential Green Chemistry Challenge, 354 USA, 106, 200, 329, 459 UV photo-oxidation. See Ultraviolet photo-oxidation UV-VIS. See Ultraviolet-visible 235

VOCs. See Volatile organic compounds Volatile organic compounds (VOCs), 30, 31 passive sampling, 54 sampler, 14 Volatilization, 27 Voltammetry, 275 Voltammetry oxygen electrode, voltammetry sensor. See Clark electrode

W Ward’s method, of clustering, 373 Water, 1–2 biogeochemical cycle of, 304 as matrix for organic and organometallic analytes, 304–305 Water Framework Directive (WFD), 59, 140–141, 190, 193 Water pollution assessment, integrated system of, 200–201, 202–204 Water sample preparation step, used mineralization techniques, 95 advanced oxidation processes for, 96 ozone oxidation, 98–99 UV photo-oxidation, 97–98 Water samples, 3, 8–11 collection of, 9–11 composite sample, 3–4 discontinuous sampling, 4 discrete sample, 3 location and sites, 9 preservation and storage. See Preservation and storage of water samples sample size, 8 sampling frequency, 11 Water-cooled atom traps (WCAT), 267 Water-soluble organic carbon (WSOC), 232 Waveguide interrogated optical system (WIOS), 161 WCAT. See Water-cooled atom traps WEA. See Whole Effluent Assessment WEER. See Whole Effluent Environmental Risk Weighting, 419 WET. See Whole Effluent Toxicity WFD. See Water Framework Directive Whole Effluent Assessment (WEA), 200 Whole Effluent Environmental Risk (WEER), 201 Whole Effluent Toxicity (WET), 200 WIOS. See Waveguide interrogated optical system Working Party on Green Chemistry, 354 WSOC. See Water-soluble organic carbon

X X-charts, 395 XAD-2, 31

V

Z

Validation of analytical procedures, 393–394 Van Dorn sampler, 14 Vibrio fischeri, 196, 207 Vibro-corers, 16

z-score, in evaluation of laboratory results, 396 Zeeman effect, 268 Zeta-score, in evaluation of laboratory results, 396 Zostera, 105